EX-96.3 9 exhibit963-technicalreport.htm EX-96.3 Document


Exhibit 96.3
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image_2.jpgTECHNICHAL REPORT SUMMARY OF THE PAMPA BLANCA OPERATION YEAR 2024

                        
    Date: April 23, 2025



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Summary
This report provides the methodology, procedures and classification used to obtain SQM´s Nitrate and Iodine Mineral Resources and Mineral Reserves, at the Pampa Blanca Site. The Mineral Resources and Reserves that are delivered correspond to the update as of December 31, 2024.
The results obtained are summarized in the following tables:
Mineral Resources 2024
MiningTotal Inferred ResourceTotal Indicated ResourceTotal Measured Resource
Tonnage (MMTon)Nitrate Grade (%)Iodine Grade (ppm)Tonnage (MMTon)Nitrate Grade (%)Iodine Grade (ppm)Tonnage (MMTon)Nitrate Grade (%)Iodine Grade (ppm)
Pampa Blanca 218 5.4 513  526 6.3 559  48 5.0 394


Mining PropertyProven Reserves (1)Average grade NitratesAverage grade Iodine
(million metric tons)(Percentage by weight)(Parts per million)
Pampa Blanca855.4%392
Mining PropertyProbable Reserves Average grade NitrateAverage grade Iodine
(million metric tons)(Percentage by weight)(Parts per million)
Pampa Blanca
(1) The tables above show the Proven and Probable Reserves before losses related to the exploitation and treatment of the mineral. Proven and Probable Reserves are affected by mining methods, resulting in differences between the estimated reserves that are available for exploitation in the mine plan and the recoverable material that is ultimately transferred to the leach pads. The global average metallurgical recovery of nitrate and iodine processes contained in the recovered material is variable in each pampa (60% to 80 %). Proven and probable reserves have a caliche thickness ≥ 2.0 m and a slope, which should not exceed 8%.
(2) All the most proven mining reserves are with the block model valued method, for which each pampa will have a cut-off benefit (BC), to maximize the economic value of each block.
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TABLE OF CONTENT

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TABLES

Table 1-1. Pampa Blanca Mineral Resources as of December 31, 2023.
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Table 7-4. Recovery Percentages at Pampa Blanca by Sectors
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Table 11-3. Block Model Dimensions
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FIGURES
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Figure 6-8. Mineralogy of Pampa Blanca Caliche.
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Figure 6-9. Maps of the Central Andes of South America (A) Digital Elevation Map with Principal Morphotectonic provinces of the Southern Central Andes labelled
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Figure 10-6. Successive leach test development procedure
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Figure 10-7. Iodine Recovery as a Function of total Salts Content.
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Figure 10-8. Parameter Scales and Irrigation Strategy in the Impregnation Stage.
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Figure 10-9. Irrigation Strategy Selection
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Figure 10-10. Nitrate and Iodine Yield Estimation and Industrial Correlation
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Figure 11-1. Block model location in Pampa Blanca Sector 4 - 5.
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Figure 11-2. Variogram Models for Iodine in Pampa Blanca Sector 5.
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Figure 11-3. Plan view of the polygons bordering The Mineral Resources Pampa Blanca Sector 5
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Figure 11-4. Swath Plots for Iodine – PB5
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Figure 11-5. Swath Plots for Nitrate – PB5
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Figure 11-6. Visual Validation of Iodine (Up) and Nitrate (Down) Estimation, Plan View – PB5
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Figure 14-5 Expansion of the Evaporation Pools plan at the Florencia de Pampa Blanca Plant.
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Figure 20-1. Pampa Blanca Adjacent Properties
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Figure 20-2. Other properties adjacent to the Project that is exploited by others
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1EXECUTIVE SUMMARY
1.1PROPERTY SUMMARY AND OWNERSHIP
Located in Sierra Gorda, province of Antofagasta, the Pampa Blanca Mine has deposits located on flatlands or "pampas" covering an area of 51,201 hectares. Exploration program results have indicated that explored areas reflect a mineralized trend hosting nitrate and iodine. Exploration has generated discoveries that, in some cases, may lead to exploitation, sales of the discovery, and generation of royalties in the future. Within this framework, in 2013 the company recorded a royalty sale of the Antucoya project to Antofagasta Minerals (copper mining).
As part of the limits belonging to SQM-Pampa Blanca, there are other properties adjacent to the project being exploited by others and there are some mining rights, which include: Algorta Norte S.A., Antofagasta Minerals, and Mina Rencoret.
1.2GEOLOGY AND MINERALIZATION
Pampa Blanca is in the physiographic unit of the Central Depression, influenced by modelling processes generated from stratigraphic units located on the eastern slopes of the Cordillera de la Costa and on the western slopes of the intermediate mountain ranges that develop to the east, where units from the Paleozoic to the recent age are found.
The Nitrate - Iodine deposits located at Pampa Blanca are immersed in an alluvial fan sedimentary environment, with the mineralization being associated with clastic sedimentary rocks (conglomerate sequences, conglomerate breccias, brecciated conglomerates and sandstones) and to a lesser extent with volcanic rocks. The main structures affecting the sector correspond to two main systems of NS and NW-SE orientations respectively, these systems generate a tectonically uplifted basin which hosts this deposit. These structures also affect the morphology of the sector, contributing to the formation of deep ravines and controlling the drainage networks.
Mineralization at Pampa Blanca is mantiform, with a wide areal distribution, forming "spots" of several kilometers in extension; the mineralization thicknesses are variable, with mantles of approximately 1.0 to 5.0 meters. The mineralogical association identified corresponds mainly to soluble sulfates of Na - K, less soluble sulfates of Ca, Chlorides, Nitrates and Iodates. Within the mineral species of interest, for Nitrates; Nitratine (NaNO3) - KNO3 (Potassium Nitrate); Hectorfloresite, Lautarite, Bruggenite as iodates.
In 2024, there was no detailed exploration program. Currently, drilling totals 20,952 reverse circulation (RC) drill holes (125,286 meter). All the drill holes were vertical. Drilling is carried out with wide grid in the first reconnaissance stage (1000 x 1000; 800 x 800; 400 x 400); to later reduce this spacing to define the resources in their different categories.
1.3MINERAL RESOURCE STATEMENT

This sub-section contains forward-looking information related to Mineral Resource estimates for the Project. The material factors that could cause actual results to differ materially from the conclusions, estimates, designs, forecast or projections in the forward-looking information include any significant differences form one or more of the material factors or assumptions that were set forth in this sub-section including a geological grade interpretation a controls and assumptions a forecast associated with establishing the prospects for economic extraction.
All available samples were used without compositing and no capping, or other outlier restriction, to develop a geological model in support of estimating Mineral Resources. Hard contacts were used between different geological units. Sectors with a drill hole grid of 50 x 50 m and up to 100 x 100 m were estimated in a three-dimensional block model using the Ordinary Kriging (KO) interpolation method in one pass. Additionally, variograms were constructed and used to support the search for ellipsoid anisotropy and linear trends observed in the data. Iodine and nitrate grade interpolation was performed using the same variogram model calculated for Iodine. In the case of sectors with drill holes grids greater than 100 x 100 m and up to 200 x 200 m were estimated in a three-dimensional block model using the Inverse Distance Weighted (IDW) interpolation method. For areas with drill holes grids of 400 x 400 m were estimated in two dimensional using the Polygon Method.
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Mineral Resources were classified using the drill hole grid. Zones with grid of 50 x 50 m up to 100 x 100 m were classified as Measured. For Indicated Mineral Resources, the zone should have a 200 x 200 m drill hole grid. To define inferred Resources a 400 x 400 m drill hole grid was used.
The Mineral Resources involves a new methodology, "block valorization", which considers for the resource, an optimal economic envelope of each pampa for a cut-off benefit (USD/Ton of ore) greater than 0.1 (BC). The parameters included in the calculation of the value of the block are: Iodine price, Nitrate price, Iodine Recovery, Nitrate Recovery, Mine Cost, Iodine Plant Cost and Nitrate Plant Cost". The block valuation methodology is stacked for measured and indicated resources (excluding reserves). The resulting inferred resources are not valued and are reported on an iodine cut-off grade (300 ppm).

The Mineral Resource Estimate, excluding Mineral Reserves, is presented in Table 1-1.

Table 1-1. Pampa Blanca Mineral Resources as of December 31, 2024.

Pampa BlancaMeasuredIndicatedM+1Inferred
Tonnage (MMTon)Nitrate Grade (%)Iodine Grade (ppm)Tonnage (MMTon)Nitrate Grade (%)Iodine Grade (ppm)Tonnage (MMTon)Nitrate Grade (%)Iodine Grade (ppm)Tonnage (MMTon)Nitrate Grade (%)Iodine Grade (ppm)
485.03945266.35595746.25452185.4513

(a)Mineral Resources are not Mineral Reserves and do not have demonstrated economic viability. There is no certainty that all or any part of the Mineral Resource will be converted into Mineral Reserves upon the application of modifying factors.
(b)The Mineral Resources are based on the application of modifying factors and due to the fact that the caliche deposits are located on the surface, part of the Measured and Indicated Mineral Resources with environmental permits and that are within the envelope of the valorization of the block greater than 3, have been converted into Mineral Reserves. As a consequence of the above, geological resources are provided excluding mining reserves, or which they are included in this Report of Measured Geological Resources, indicated and inferred in this Summary of the Technical Report.

(c)Comparisons of values may not add due to rounding of numbers and the differences caused by use of averaging methods.
(d)The units “Mt”, “ppm” and “%” refer to million tons, parts per million, and weight percent respectively.
(e)The Resource Mineral involves a cut-off benefit (USD/Ton of ore) greater than 0.1 and caliche thickness ≥ 2.0 m.
(f)As the mineral resources estimation process is reviewed and improved each year, mineral resources could change in terms of geometry, tonnage or grades.

Density was assigned to all materials with a default value of 2.1 (ton/m3), this value comes from several analysis made by SQM in Pampa Blanca and other operations.
The QP is not aware of any environmental, permitting, legal, title, taxation, socioeconomic, marketing, political or other relevant factors that could materially affect the Mineral Resource Estimate that are not discussed in this Technical Report.
1.4MINERAL RESERVE STATEMENT
This sub-section contains forward-looking information related to Mineral Reserve estimates for the Project. The material factors that could cause actual results to differ materially from the conclusions, estimates, designs, forecast or projections in the forward-looking information include any significant differences from one or more of the material factors or assumptions that were set forth in this sub-section including Mineral Resource model tons and grade, modifying factors including mining and recovery factors, production rate and schedule, mining equipment productivity, commodity market and prices and projected operating and capital costs.
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The Measure Mineral Resources defined by drill hole grid 50 x 50 m and up to 100 x 100 m; and evaluated using 3D blocks and Ordinary Kriging are considered as high level of geological confidence are qualified as Proven Mineral Reserves.(See Table 12.2).
The Indicate Mineral Resources defined by drill holes grids greater than 100 x 100 m up to 200 x 200 m; and evaluated using 3D blocks model and Inverse Distance Weighted (IDW) interpolation method is considered as medium level of geological confidence and qualified as Probable Mineral Reserves.
The Mineral Reserves are based on the block valuation methodology, which considers for the resource, an optimal economic envelope of each pampa for a Cut-off Benefit (USD/Ton of ore) greater than 3. The parameters included in the calculation of the value of the block are: Iodine price, Nitrate price, Iodine Recovery, Nitrate Recovery, Mine Cost, Iodine Plant Cost and Nitrate Plant Cost", another restriction for reserves is a caliche thickness ≥ 2.0 m and a slope, which should not exceed 8%. Economic viability is demonstrated in discounted cash flow after taxes (see Section 19). All Mineral Reserves are defined in sectors with environmental permits (RCA).
Some sectors belong to Pampa Blanca mine started the exploitation prior the year 1997, thus it didn´t need developing an EIA and obtain the administrative authorization (RCA) to operate according to the current environmental legislation in Chile (Ley 19.300 Bases Generales del Medio Ambiente, 01-March-1994). These sectors have an “Authorization Sectorial” (operation permit) that allow to SQM operates and extract the resources estimated using heap leaching structures (Operation Permit with heap Leah) or traditional methods (“bateas”) (Operation Permit without heap Leah) to obtain enriched fresh brine in Iodine and Nitrates.
SQM has some sector of Pampa Blanca mine with different status process of environmental license or operational permit, thus, the estimated resources without RCA can´t be consider as reserves (Table 1-2).

Table 1-2. Environmental Status at Pampa Blanca Mine.
Pampa BlancaOperational Permit With Heap LeachingWithout RCA
Measured Resources4817
Proven Reserves85
Indicated Resources526
Probable Reserves
RCAEnvironmental Qualification Resolution Administrative document that establishes that the environmental Impact Assessment Process has been Approved, Rejected, or Approved with Conditions
Operational PermitOperation permit ("Autorización Sectorial") that corresponds to mines that began activity prior to 1997. The method of exploitation considered in the permit can't be modified, unless an EIA is carried out to obtain the corresponding permits (RCA)
Without RCASectors without RCA; so the Resources Indicated under this category are not considered as Probable Reserves

In these criteria, Proven Reserves Mineral at Pampa Blanca are estimated in to 85 million tons (Mt) with an estimated average nitrate grade of 5.4% and 392 ppm iodine.
All Probable Reserves were recategorized to Proven Reserves, therefore there are no longer Proven reserves for this update.
Mineral Reserves are stated as in-situ ore.

Table 1-3. Mineral Reserve at the Pampa Blanca Mine (Effective 31 December 2024)
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Proven ReservesProbable ReservesTotal Reserves
Tonnage (Mt)8585
Iodine Grade (ppm)392392
Nitrate Grade (%)5.45.4
Iodine (kt)33.533.5
Nitrate (kt)4,6134,613

Notes:
(1)The Mineral Reserves are based on a Cut-off Benefit (BC) greater than 3 USD/t, a caliche thickness ≥ 2.0 m. and a restriction of sectors with slopes not greater than 8%.
(2)Proven Minerals Reserves are based on Measured Mineral Resources at the criteria described in (a) above.
(3)Probable Mineral Reserves are based on Indicated Mineral Resources based on the criteria described in (a) above, calculations were made using a model estimated by IDW.
(4)Mineral Reserves are stated as in-situ ore (caliche) as the point of reference.
(5)The units “Mt”, “kt”; “ppm” and “%” refer to million tons, kilotons; parts per million, and weight percent respectively.
(6) Mineral Reserves are based on an Iodine price of 42.0 USD/kg. Miner is also based on economic viability as demonstrated in an after-tax discounted cashflow (see Section 19).
(7)Marco Fazzi and Freddy Ildefonso are the QP responsible for the Mineral Resources.
(8)The QP is not aware of any environmental, permitting, legal, title, taxation, socioeconomic, marketing, political or other relevant factors that could materially affect the Mineral Reserve estimate.
(9)Comparison of values may not total due to rounding of numbers and the differences caused by use of averaging methods.

1.5MINE DESIGN, OPTIMIZATION, AND SCHEDULING
At Pampa Blanca the total amount of Caliche extraction reached in 2024 was 5.8 million tons (Mt). Caliche production for the Long Term (MP) form 2025 through 2030 is 5.5 Mt per year and for the period 2031-2040 is 5.2 Mt; with an average iodine grade of 392 ppm and nitrate grade of 5.4%.
The mining procedure at Pampa Blanca involves the following processes:
Removal of surface layer and overload (between 0.50 to 2.0 m thick).
Caliche extraction, up to a maximum depth of 6 m, through explosives (drill & blast).
Caliche loading, using front-end loaders.
Transport of the mineral to heap leach, using mining trucks (rigid hopper) of high tonnage (100 to 150 Tones).
Construction of heap leach to accumulate a total of 0.5 to 1 Mt, with heights of 7 to 15 m and a crown area of 40,000 to 65,000 square meters (m²).
The physical stability analysis performed by SQM indicates that these heaps are stable for long-term stable, and no slope modification is required for closure.
Continuous irrigation of heap leach is conducted to complete the leach cycle. The cycle of each heap lasts approximately 400 to 500 days and during this time, heap height decreases by 15% to 20%.
The criteria set by SQM to establish the mining plan correspond to the following:
Caliche thickness ≥ 2.0 m
Overburden thickness ≤ 3.0 m
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Barren / Mineral Ratio < 1.0
Unit sales Price for prilled Iodine 42,000 US$/Ton and a unit total cost of 32.1 US$/Tons (mining, leaching and plant processing).
The caliche will be extracted using the traditional methods of drill & blast.
In Pampa Blanca mine, initial concentration process started with a leaching in situ by means of heaps (leaching pad) irrigated by drip/spray to obtain an iodine and nitrate enriched solution that is sent to treatment plants to obtain the final products.
In heap leaching processes, the total water consumptions range from 0.45 to 0.47 m³/ton of “caliches”.
Leaching process yields are set at around 60% for iodine and 40% for nitrate in ROM heap leaching (material extracted with traditional method drill & blast).
Other mining facilities besides heaps are solutions ponds (brine, blending, intermediate solution -SI-) and water and back-up ponds (brine and intermediate solution). From brine pond, the enriched solutions were sent to the iodide plants via HPDE pipes.
Given the production factors set in mining and leaching processes (69.0% for prilled Iodine and 33.3% for Nitrates Salts that are average values), a total production of 23.1 kt of Iodine and 1,535 kt of nitrate salts for fertilizers is expected for this period (2025- 2040) from lixiviation process to treatment plants.
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1.6METALLURGY AND MINERAL PROCESSING

1.6.1 Metallurgical Testing Summary
The test work developed is aimed at determining the susceptibility of raw materials to production by means of separation and recovery methods established in the plant, evaluating deleterious elements, to establish mechanisms in the operations and optimize the process to guarantee a recovery that will be intrinsically linked to the mineralogical and chemical characterization, as well as physical and granulometric of the mineral to be treated.
Historically, SQM Nitrates, through its Research and Development area, has conducted tests at plant and/or pilot scale that have allowed improving the knowledge about the recovery process and product quality through chemical oxidation tests, solution cleaning and recently, optimization tests of leaching heap operations, through the prior categorization of the ore to be leached.
SQM's analysis laboratories located in the city of Antofagasta and the Iris Pilot Plant Laboratory (Nueva Victoria) perform physicochemical, mineralogical, and metallurgical tests. The latter allow to know the behavior of the caliche bed against water leaching and thus support future performance. In addition, the knowledge generated contributes to the selection of the best irrigation strategy to maximize profit and the estimation of recovery at industrial scale by means of empirical correlations between the soluble content of caliches and the metallurgical yields of the processes.

1.6.2 Mining and Mineral Processing Summary
The production process begins with mining of “Caliche” ore. The ore is heap-leached to generated iodate & nitrate rich leaching solutions referred to by SQM as “Brines”. The brines are piped to processing plants where the iodate is converted to iodide, which is then processed to obtain pelleted (“Prilled”) iodine.
The operation of the Pampa Blanca mine was suspended in 2010; During the second half of 2022, it reopens, with an initial production of 0.7 Mt charged to leaching piles during 2022. The Iodate Plant is in operation at the end of March 2023.
The material collected in a "final product" field corresponds to salt harvesting from the "Florencia Solar Evaporation Plant" resulting from an extraction process where waste salts (sodium chloride, magnesium, and sodium sulfates) and high sodium nitrate (NaNO3) salts were separated and harvested. The high sulfate salts are used in the impurity abatement system where they allow an increase in nitrate recovery in the evaporation ponds process.
The surface area authorized for mining at Pampa Blanca is 10,187 ha; caliche extraction at Pampa Blanca is 5.5 million tons per year (Mtpy).
1.7CAPITAL AND OPERATING COSTS
This section contains forward-looking information related to capital and operating cost estimates for the Project. The material factors that could cause actual results to differ materially from the conclusions, estimates, designs, forecast or projection in the forward-looking information include any significant differences from one or more of the materials factors or assumptions that were set forth in this section including prevailing economic conditions continue such that projected capital costs, labor and equipment productivity levels and that contingency is sufficient to account for changes in material factors or assumptions.
The annual production estimates were used to determine annual estimates of capital and operating costs. All cost estimates were in 2024 USD. Annual operating costs were based on historical operating costs, material movements and estimated unit costs provided for SQM. These including mining, leaching, iodine and nitrate production. Ore capital costs included working capital and closure costs. Annual total operating cost of 10.1 USD/ Ton caliche to 11.5 USD/Ton of caliche, with an average total operating cost of 10.5 USD/ Ton of caliche over the Long Term (MP).
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1.8ECONOMIC ANALYSIS
This section contains forward-looking information related to economic analysis for the Project. The material factors that could cause actual results to differ materially from the conclusions, estimates, designs, forecast or projection in the forward-looking information include any significant differences from one or more of the materials factors or assumptions that were set forth in this sub section including estimated capital and operating costs, project schedule and approvals timing, availability of funding, projected commodities markets and prices.
All costs were assumed in 2024 USD.
For the economic analysis a Discounted Cashflow (DCF) model was developed.
An iodine sales price of 42,000 USD/Ton and a nitrate salt for fertilizer price of 323 USD/Ton was used in the discounted cashflow. The imputed nitrate salts for fertilizer price of 323 USD/Ton were estimated based on average price for finished fertilizer products sold at Coya Sur of 820 USD/Ton, less 497 USD/Ton for production cost at Coya Sur.
QP believes these prices reasonably reflect current market prices and are reasonable to use as sales prices for the economic analysis for this Study.
The discounted cashflow establishes that the Mineral Reserves estimate provided in this report are economically viable. The base case NPV is estimated to be USD 273 Million. The Net Present Value for this study is most sensitive to operating cost and sales prices of both iodine and nitrates.
QP considers the accuracy and contingency of cost estimates to be well within a Prefeasibility Study (PFS) standard and enough for the economic analysis supporting the Mineral Reserve estimated for SQM.
1.9CONCLUSIONS AND RECOMMENDATIONS
Marco Fazzi QP of Mineral Resources and Mineral Reserves concludes that the work done in the review of this TRS includes adequate details and information to declare the Mineral Reserves. In relation to the resource treatment processes, the conclusion of the responsible QP, Gino Slanzi, is that appropriate work practices and equipment, design methods and processing equipment selection criteria have been used. In addition, the company has developed new processes that have continuously and systematically optimized its operations.
Some recommendations are given in the following areas:
Continue with the improvements for the Qa-Qc program to integrate it to Acquire System manages to align with the best practices of the industry, facilitating with this a more robust quality control.
It is considered important to evaluate the leachable material through heap leaching simulation, which allows the construction of a conceptual model of caliche leaching with a view to secondary processing of the riprap to increase the overall recovery. It is recommended to continue with the research work of the geometallurgical model to determine the real recovery to the increase of water.
Environmental issues include leachate or acid water management, air emissions management, tailings dump management, and leachate riprap.
Audit with an external company of the entire resource estimation process, that is, expert review of drilling database, resource estimation, and reserve valuation
All the above recommendations are considered within the declared CAPEX/OPEX and do not imply additional costs for their execution.








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2INTRODUCTION
This Technical Summary Report (TRS) was prepared by SQM's team of professionals and external advisors for Sociedad Química y Minera de Chile (SQM), in accordance with the requirements of Regulation SK, Subpart 1300 of the United States Securities Exchange Commission (SEC), hereinafter referred to as SK 1300.
2.1TERMS OF REFERENCE AND PURPOSE OF THE REPORT
At Pampa Blanca, SQM produces nitrate salts (sodium nitrate and potassium nitrate) and iodine, by heap leaching and evaporation. The effective date of this TRS report is December 31, 2024.
This TRS uses English spelling and Metric units of measure. Grades are presented in weight percent (wt.%). Costs are presented in constant US Dollars as of December 31, 2024.
Except where noted, coordinates in this TRS are presented in metric units using the World Geodesic Reference System (PSAD) 1956 Universal Transverse Mercator (UTM) ZONE 19 South (19S).
The purpose of this TRS is to report Mineral Resources and Mineral Reserves for SQM’s Pampa Blanca operation.
2.2SOURCE OF DATA AND INFORMATION
This TRS is based on information from SQM and public domain data. All information is cited throughout this document and is listed in the final "References" section at the end of this report. Table 2-1 provides the abbreviations (abbv.) and acronyms used in this TRS.
Table 2-1 Abbreviations (abbv.) and acronyms
Acronym/Abbv.Definition
minute
'second
%percent
°degrees
°Cdegrees Celsius
100T100 truncated grid
AAAtomic absorption
AAAAndes Analytical Assay
AFAweakly acidic water
AFNFeble Neutral Water
AjayAjay Chemicals Inc.
ASAuxiliary Station
ASGAjay-SQM Group
BFBrine Feble
BFNNeutral Brine Feble
BWnabundant cloudiness
CIMCentro de Investigación Minera y Metalúrgica









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Acronym/Abbv.Definition
cmcentimeter
CUWater consumption
COMMining Operations Center
CSPConcentrated solar power
CONAFNational Forestry Development Corporation
DDHdiamond drill hole
DGAGeneral Directorate of Water
DTHdown-the-hole
EB 1Pumping Station No. 1
EB2Pumping Station No. 2
EIAenvironmental impact statement
EWeast-west
FCfinancial cost
FNWfeble neutral water
ggram
Ggravity
GUgeological unit
g/ccgrams per centimeter
g/mLgrams per milliliter
g/tongrams per ton
g/Lgrams per liter
GPSglobal positioning system
hhour
hahectare
ha/yhectares per year
HDPEHigh-density Polyethylene
ICHindustrial chemicals
ICPinductively coupled plasma
ISOInternational Organization for Standardization
kgkilogram
kh
horizontal seismic coefficient
kg/m3
kilogram per cubic meter
kmkilometer
kv
vertical seismic coefficient
kN/m3
kilonewton per cubic meter
km2
square kilometer
kPaKilopascal
ktkilotonne
ktpdthousand tons per day
ktpykilotonne per year
Acronym/Abbv.Definition
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kUSDthousand USD
kVkilovolt
kVakilovolt-amperes
L/h-m2
liters per hour square meter
L/m2 /d
liters per square meter per day
L/sliters per second
LRLeaching rate
LCD/LEDliquid crystal displays/light-emitting diode
LCYCaliche and Iodine Laboratories
LdTEmedium voltage electrical transmission line
LIMSLaboratory Information Management System
LOMlife-of-mine
mmeter
M&Amergers and acquisitions
m/km2
meters per square kilometer
m/smeters per second
m2
square meter
m3
cubic meter
m3 /d
cubic meter per day
m3 /h
cubic meter per hour
m3 /ton
cubic meter per ton
maslmeters above sea level
mbglmeter below ground level
mbslmeters below sea level
mmmillimeter
mm/ymillimeters per year
Mpamegapascal
Mtmillion ton
Mtpymillion tons per year
MWmegawatt
MWh/yMegawatt hour per year
NNEnorth-northeast
NNWnorth-northwest
NPVnet present value
NSnorth south
O3
ozone
ORPoxidation reduction potential
PLSpregnant leach solution
PMAparticle mineral analysis
ppbvparts per billion volume
ppmparts per million
Acronym/Abbv.Definition
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PVCPolyvinyl chloride
QAQuality assurance
QA/QCQuality Assurance/Quality Control
QCQuality control
QPQualified Person
RCreverse circulation
RCAenvironmental qualification resolution
RMRRock Mass Rating
ROMrun-of-mine
RPMrevolutions per minute
RQDrock quality index
SGSpecific gravity
SECSecurities Exchange Commission of the United States
SSESouth-southeast
SEIAEnvironmental Impact Assessment System
MMAMinistry of Environment
SMAEnvironmental Superintendency
SNIFANational Environmental Qualification Information System (SMA online System)
PSAEnvironmental Following Plan (Plan de Seguimiento Ambiental)
SEMTerrain Leveler Surface Excavation Machine
SFFspecialty field fertilizer
SIintermediate solution
SINGNorte Grande Interconnected System
S-K 1300Subpart 1300 of the Securities Exchange Commission of the United States
SMSurface Mining
SM (%)salt matrix
SPMsedimentable particulate matter
Srrelief value, or maximum elevation difference in an area of 1 km²
SSsoluble salt
SXsolvent extraction
tton
TRIrrigation rate
TASsewage treatment plant
TEA projectTente en el Aire Project
tpytons per year
t/m3
tons per cubic meter
tpdtons per day
TRSTechnical Report Summary
ug/m3
microgram per cubic meter
USDUnited States Dollars
USD/kgUnited States Dollars per kilogram
USD/tonUnited States Dollars per ton
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Acronym/Abbv.Definition
UTMUniversal Transverse Mercator
UVultraviolet
VECVoluntary Environmental Commitments
WGSWorld Geodetic System
WSFWater soluble fertilizer
wt.%weight percent
XRDX-Ray diffraction
XRFX-ray fluorescence

2.3DETAILS OF INSPECTION
The most recent site visit dates for each Qualified Person (QP) are listed in Table 2-2:
Table 2-2. Summary of site visits made by QPs to Pampa Blanca in support of TRS Review
Qualified Person (QP)ExpertisDate of VisitDetails of Visit
Marco FazziGeologydec-24Pampa Blanca Mine and Facilities
Gino SlanziMetallurgy and Mineral Processingmar-24Inspection of Iodine Plants, Mine and Leaching Piles
Freddy IldefonsoGeologydec-24Pampa Blanca Mine and Facilities

During the site visits to the Pampa Blanca Property, the QPs, accompanied by SQM technical staffs:
Visited the mineral deposit (caliche) areas.
Inspected drilling operations and reviewed sampling protocols.
Reviewed core samples and drill holes logs.
Assessed access to future drilling locations.
Viewed the process though mining, heap leaching.
Reviewed and collated data and information with SQM personnel for inclusion in the TRS.
2.4PREVIOUS REPORTS ON PROJECT
Technical Report Summary prepared by WSP Consulting Chile (WSP), March 2022.
Technical Report Summary prepared by SQM S.A, March 2023.
Technical Report Summary prepared by SQM S.A, April 2024.


3DESCRIPTION AND LOCATION
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3.1LOCATION
The Project is located in Antofagasta Region, Sierra Gorda commune, approximately 100 km northeast of the city of Antofagasta and 25 km northeast of the town of Baquedano (SQM, 2019). The property is located between the UTM coordinates (WGS 84, zone 19S) 430,000 E - 7,460,000 N and 430,000 E - 7,400,000 N.

Figure 3-1. General Location Map
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3.2MINERAL TITLES, CLAIMS, RIGHTS, LEASES AND OPTIONS
SQM currently has 4 mineral properties located in the north of Chile, in the First Region of Tarapacá (I) and Second Region of Antofagasta (II). These are the Nueva Victoria, María Elena, Pedro de Valdivia and Pampa Blanca properties. All properties cover a combined area of approximately 289,781 ha and has been make prospecting grid resolution of 400 x 400 m or finer.
The Pampa Blanca Property covers an area of approximately 75,802 hectares and comprised of 53 mining properties Table 3-1.
Table 3-1. Total Number of Mining Properties to Pampa Blanca Site.
Mining Properties
LENKA 101 1-20COLINA 1 1-30LENKA 65 1-30
LENKA 65 61-90LENKA 64 II 1-30MIEDO 52 1-90
CELIA 1-33LENKA 55 91-120COLINA 6 1-10
LENKA 75 II 31-60COPO 1 1-30LENKA 65 31-60
LENKA 65 91-120LENKA 64 II 31-60MIEDO 54 1-40
CARBONATO 13 41-70LENKA 54 121-150CARBONATO 12 31-60
LENKA 75 II 61-90COPO 2 1-30MIEDO 60 1-60
LENKA 65 121-150LENKA 64 II 61-90PAULO I 1-28
CARNONATO 13 71-100LENKA 54 61-90CARBONATO 12 61-80
LENKA 75 II 91-120MIEDO 55 1-60MIEDO 61 1-40
LENKA 55 1-30LENKA 64 II 91-120CHACABUCO 1-9
COLINA 2 1-30LENKA 54 91-120CARBONATO 13 1-40
LENKA 75 II 1-30MIEDO 50 1-17MIEDO 63 1-90
LENKA 55 31-60LENKA 56 III 1-50AURELIA 1-9
COLINA 3 1-30LENKA 55 121-150CARBONATO 12 1-30
LENKA 64 II 121-150MIEDO 51 1-14PAULO IV 1-12
LENKA 55 61-90COLINA 5 1-20ESTACA BOLIVIANA V
COLINA 4 1-30CONDELL 1-39

3.3MINERAL RIGHTS
SQM owns mineral exploration rights over 1,538,919 ha of land in the I and II Regions of northern Chile and is currently exploiting the mineral resources over less of 1% of this area (as of Dec 2024).

3.4ENVIRONMENTAL IMPACTS AND PERMITTING
The Plant has the following environmental authorizations, whose approval is detailed in the corresponding Environmental Qualification Resolution (RCA) issued by the authority (Environmental Evaluation Service "SEA")
Environmental Qualification Resolution No. 021/1999 approves the Environmental Impact Assessment (EIA) "Florencia Solar Evaporation Plant".
Environmental Qualification Resolution No. 278/2010 approves the EIA "Pampa Blanca Mine Zone".
Environmental Qualification Resolution No. 319/2013 approves EIA "Pampa Blanca Expansion" (this project has not been executed to date; this request is not considered).
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Currently, the Environmental Impact Statement (EIS) "Modification of the Pampa Blanca Mining Facility through the Incorporation of a New Waste Salt Storage Area" is under environmental assessment, for which the first round of responses to the observations received by the services was delivered.

Additionally, the environmental assessment of the Pampa Blanca Seawater Pumping System project is being prepared, which includes the mine area and the seawater pumping system for future operation.
On the other hand, the Exempt Resolutions issued by the National Geology and Mining Service (SERNAGEOMIN) associated with the site correspond to:
Exempt Resolution N°821/2009 authorizing Pampa Blanca Closure Plan.
Exempt Resolution N°368/2010 authorizing the Temporary Closure of Pampa Blanca.
Exempt Resolution N°1346/2012 authorizing the extension of the Temporary Closure, Pampa Blanca Closure Plan.
Exempt Resolution N°1424/2015 that approves the project (Valorization) of the Closure Plan of the Pampa Blanca Mining Plant.
Exempt Resolution N°2873/2017 that favorably qualifies the guarantee accumulated to 2017 of the valorization projects for the Closure Plan of the Mining Mine "Pampa Blanca".
Exempt Resolution N°802/2019 that approves the project Temporary Closure Plan for the Pampa Blanca Mine.
Exempt Resolution N°1304/2020 that approves the Expansion of the Temporary Closure Plan for the Pampa Blanca Mine.

Exempt Resolution N°0292/2023 that approves of the Closure, Pampa Blanca Closure Plan.

Exempt Resolution N°0292/2023 Authorization for waste disposal -Storage of waste as a waste dump”
3.5OTHER SIGNIFICANT FACTORS AND RISKS
SQM’s operations are subject to certain risk factors that may affect the business, financial conditions, cash flow, or SQM’s operational results.
The factors or risks are described below:
The risk of obtaining final environmental approvals from the necessary authorities promptly. Sometimes, obtaining permits can cause significant delays in the execution and implementation of new projects.
Risks related to be a company based in Chile; potential political risks as well as changes to the Chilean Constitution and legislation that could conceivably affect development plans, production levels, royalties and other costs.
Risks related to financial markets.
3.6ROYALTIES AND AGREEMENTS
Apart from paying standard mineral royalties to the Government of Chile, in compliance with the Chilean Royalty Law, SQM has no obligations to any third party in respect of payments related to licenses, franchises or royalties for its Pampa Blanca Property.

4ACCESSIBILITY, CLIMATE, LOCAL RESOURCES, INFRASTRUCTURE AND PHYSIOGRAPHY
This section of the TRS provides a summary of the physical setting of the Pampa Blanca Property, access to the property and relevant civil infrastructure.
4.1TOPOGRAPHY

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Sierra Gorda is located at an average elevation of 1.100 m.a.s.l, it is geographically located in the Atacama Desert, which extends over a semi-plain between the east of the pre-Andean foothills and the eastern slopes of the coastal mountain range (SQM, 2019).

In addition, considering as relief (Sr) represents the rugosity of the landscape within a unit area, the Sr factor is defined as the maximum difference in elevation in an area of 1 km² (Table 4-1).

Table 4-1. Relative Slope value Rr, its classification and resulting value factor Sr.
Slope CategoryFromTo
Slope Value Rr (m/Km2)
Sr factor
Very Low4.3°0-750
Low4.3°9.94°76-1751
Moderate 9.94°16.71°176-3002
Medium16.71°26.58°301-5003
High26.58°501-8004
Very HighSlopes > 38.66>8005
Figure 4-1 shows that the study area has slopes ranging from 0 to 39°. Although most of the area is almost flat (Figure 4-1), the lower slopes represent a low relief factor, close to 4 and 9 degrees, especially in the property area. The steepest slopes are seen in the western sector, close to the coast, due to the coastal escarpment.
Due to the extreme natural and anthropogenic intervention characteristics of the study area, the area lacks the presence of flora communities or wildlife populations and is not an area with potential for the establishment and development of flora and fauna communities, except in some sectors with the presence of brackish groundwater where it would be possible to observe the species Tessaria absinthioides (Soroma or Brea), but this was not recorded in the project area (SQM, 2019).

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Figure 4-1. Slope parameter map Sr and elevation profile trace AA"
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4.2VEGETATION
The Pampa Blanca Property is a desert landscape devoid of vegetation cover.
4.3ACCESSIBILITY AND TRANSPORTATION TO THE PROPERTY
At Pampa Blanca, the Company operates mining operations located 100 kilometers northeast of Antofagasta. There is access by plane from the Andrés Sabella airport, located in Antofagasta, and then the Ruta 5 Norte highway in the town of Sierra Gorda.
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4.4CLIMATE AND LENGTH OF OPERATING SEASON
The area is predominantly a normal desert climate, with clear skies almost all year round, low rainfall, minimum atmospheric humidity levels, and significant daily temperature fluctuations. The average rainfall in the area is 1 mm per year and occurs mainly in the winter months. Intense precipitation does not exceed 10 mm, with years without precipitation most frequent. The average annual temperature is around 18°C with a seasonal amplitude of 7° and an average daily amplitude of 20°C in the winter months and 15° in the summer months. Regarding evaporation, the annual average is 8 mm/day with a fluctuation between 4.5 mm/day in the winter months and 12.5 mm/day in the summer months.
Winds in a predominantly westerly direction are present in the area, although with daily variations. Wind speeds average between 20 - 25 km/h, with the highest speeds occurring around 14:00 hours with figures in the order of 30 km/h (eventually generating gusts of up to 50 km/h), and the lowest speeds during the morning, around 8:00 hours between 10 to 15 km/h. No accentuated changes are observed throughout the year' s seasons.
4.5INFRASTRUCTURE AVAILABILITY AND SOURCES
In the Pampa Blanca mining area, the following facilities and infrastructures can be found.
Caliche mining areas.
Industrial water supply.
Heap leaching operation.
Mine Operation Centers (COM): Ponds for brine accumulation (poor solution, intermediate and rich solution ponds), recirculated feble brine ponds, industrial water ponds, and their respective pumping and impulsion systems.
Iodide plant: includes furnaces for SO2 generation, absorption towers with their respective tanks, gas scrubbing system, solvent extraction plants (SX) and their respective tanks, and brine wells with their pump systems.
Evaporation Ponds: includes neutralization plant and solar evaporation ponds.
Auxiliary facilities: staff offices and facilities, Reverse Osmosis Plant, and TAS plant.
Ancillary facilities: offices, warehouses, temporary waste storage yard, among others.
Water rights for the supply of surface and groundwater exist near production facilities. The main water sources for nitrate and iodine facilities in Pedro de Valdivia, Pampa Blanca and Coya Sur were the Loa and Salvador rivers that run near the production facilities. Currently the water used in the operation is purchased from Aguas Antofagasta.
There are external suppliers to provide industrial water supply. Water is extracted, pumped and transported through a network of pipes, pumping stations and power lines that allow industrial water where it is required.

5HISTORY
Commercial exploitation of caliche mineral deposits in northern Chile began in 1830's when sodium nitrate was extracted from the mineral for use in explosives and fertilizers production. By the end nineteenth century, nitrate production had become Chile's leading industry, and, with it, Chile became a world leader in nitrates production and supply. This boom brought a surge of direct foreign investment and the development of the Nitrate “Offices” or “Oficinas Salitreras” as they were called.
Synthetic nitrates' commercial development in 1920´s and global economic depression in l930´s caused a serious contraction of the Chilean nitrate business, which did not recover in any significant way until shortly after World War II. Post-war, widely expanded commercial production of synthetic nitrates resulted in a further contraction in Chile's natural nitrate industry, which continued to operate at depressed levels into their 1960´s.
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Numerous companies operated in this sector during the first decades of the 20th century, including the Oficina Salitrera Chacabuco, located in the central canton of Antofagasta and built between 1920 and 1924, which ceased operations in 1940. Its owners were Anglo Nitrate Company Ltd. and later Anglo Lautaro Nitrate Company. In 1968 the latter company sold the office to Sociedad Química y Minera de Chile, and in 1971 it was declared a National Monument to preserve the testimony of what was the industrial development of nitrate in Chile.
SQM has worked on waste material from previous operations since 1987, and in 1997 began extracting ore in situ. The ore from Pampa Blanca, at that time, was transported in trucks to the leaching piles to obtain iodine and nitrate. In February 2010, mining operations in Pampa Blanca were stopped, with the subsequent temporary closure of the mine, until its reopening in the second half of 2022.

6GEOLOGICAL SETTING, MINERALIZATION AND DEPOSIT
6.1REGIONAL GEOLOGICAL SETTING
In Chile, the nitrate-iodine deposits are in the intermediate basin, limited to the east by the Coastal Range (representing the Jurassic magmatic arc) and the Precordillera (associated to the magmatic activity originating from the mega Cu-Au deposits in northern Chile), generating a natural barrier for their deposition and concentration.
The salt and nitrate deposits of northern Chile occur in all topographic positions from hilltops and ridges to the centers of broad valleys (Ericksen, 1981). They are hosted in rocks of different ages and present very varied lithologies; however, a distinctive feature is that they are always related in some way to a key unit known as the Saline Clastic Series (CSS - Late Oligocene to Neogene). The CSS comprises mainly siliciclastic and volcanoclastic sandstones and conglomerates produced by erosion and re-sedimentation of pre-existing rocks of the Late Cretaceous-Eocene volcanic arc. This key stratigraphic unit includes rocks deposited under a range of sedimentary environments including fluvial, eolian, lacustrine, and alluvial, but all were developed primarily under arid conditions. The upper parts of CSS include lacustrine and evaporitic rocks composed mainly of sulfates and chlorides. The outcrop of CSS always lies to the west of the ancient Late Cretaceous-Eocene volcanic arc, covering the present-day topography (Chong et al., 2007).

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Figure 6-1. Geomorphological scheme of saline deposits in northern Chile.
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Note: Nitrate deposits are restricted to the eastern edge of the Coastal Range and in the Central Basin (Taken from Gajardo, A & Carrasco, R. (2010). Salares del Norte de Chile: Potential Lithium Source. SERNAGEOMIN, Chile).
Most of the nitrate deposits in Chile are found in the provinces of Tarapacá and Antofagasta, with more northerly occurrences in Tarapacá largely restricted to a narrow band along the eastern side of the Coastal Range; while, to the south they extended extensively not only in the Coastal Range, but also in the Central Valley and the Andean Front (Garret, 1983). Extremely rare minerals are present in this type of deposits, among which we find nitrates, nitrate-sulphates, chlorides, perchlorates, iodates, borates, carbonates and chromates. The mineralization occurs as veins or impregnations filling pores, cavities, desiccation polygons and fractures of unconsolidated sedimentary deposits; or as a massive deposit forming a consolidated to semi-consolidated cement as extensive uniform mantles cementing the regolith, called caliche.
In this region are recognized 5 morpho structural units of N-S direction. (Perez, 2013). (Figure 6-2) In the extreme west is the Coastal Cordillera, with elevations between 1,500 and 2,000 m.a.s.l. where Middle Jurassic to Early Cretaceous intrusive and volcano-sedimentary rocks outcrop and are cut by the Atacama Fault Zone. To the east, the Central Depression with an altitude of 1,000 to 1,200 m.a.s.l, where the nitrate deposits are found, is filled mainly with Neogene alluvial deposits and Meso-Cenozoic volcano sedimentary rocks. Bordering the Central Depression to the east is the Precordillera relief, which rises to 3,000 to 4,000 m.a.s.l., and where metamorphic and intrusive Paleozoic rocks outcrop and Mesozoic marine sedimentary rocks, thanks to the Domeyko Fault System. The Western Cordillera contains the current volcanic zone and reaches heights of over 6,000 m. in the volcanic edifices, marking the western limit of the Andes Mountains. Finally, to the east, we find the Altiplano-Puna plateau zone, where the Precambrian basalt Puna plateau, up Precambrian to Paleozoic basement is extensively covered by Neogene to Quaternary volcanic deposits (Kay and Coira, 2009).

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Figure 6-2. a) Current Climatic Zones in the western margin of South America (Hartley and Chong, 2002). b) Morpho structural domains according to Hartley et al.(2005). AFS: Atacama Fault System. DFS: Domeyko Fault System. c) SRTM 90 digital elevation model and nit
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Figure 6-3. Simplified Geologic map. Modified from Marinovic et al. (1995), Marinovic and García (1999), Geologic Map of Chile, 2003
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The Atacama Desert forms a large part of the Hyperarid portion of the most important desert in western South America, the Peru-Chile Desert. The hyperaridity is due to the scarcity of precipitation in the area, which does not exceed 10 mm/year (Vargas et al., 2006; Garreaud et al., 2010). Due to the above, in the Atacama Desert there are very low erosion rates (Nishizumi et al., 1998), which has favored the accumulation and preservation of diverse and highly soluble minerals in the soil and in the nitrate crust beneath it.
The nitrate deposits of Atacama are also singular due to the presence of unusual, oxidized components such as iodates, chromates, and perchlorates, hosted by a complex mineral bed ~0,2 to 3,0 m thick composed of nitrates, sulfates and chlorides.


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6.2LOCAL GEOLOGY
The Nitrate - Iodine deposits located in the sector called Pampa Blanca are immersed in an alluvial fan sedimentary environment. The mineralization is associated with clastic sedimentary rocks (conglomerate sequences, conglomerate breccias, brecciated conglomerates and sandstones) and in lesser occurrence with volcanic rocks. The mineralization is found in the form of vein lets in volcanic rocks and as cement in sedimentary rock.
The main structure affecting the sector corresponds to two main systems of NS and NW - SE orientations respectively. These systems generate a tectonically uplifted basin which hosts the deposit. Likewise, the structures affect the morphology of the sector contributing to the formation of deep creeks and controlling the drainage networks.
The lithological units are described below (Figure 6-4):
Azabache Formation (TT)
The outcrops of this formation are constituted by a sequence of lavas of intermediate to acid composition; mainly formed by andesites, lithics tuffs and rhyolites.
Salar De Navidad Strata (PZ)
This name has been given to a sequence of meta-sedimentary rocks made up of quartzifer continental sediments, shales, siltstones and slates. This unit is assigned to the Paleozoic and outcrops in reliefs located south of the Mar Muerto Salt Lake.
La Negra Formation (JV)
These units are widely distributed throughout the Central Depression, constituting the ridges and island hills that interrupt the monotony of the saline sedimentary fills.
The stratigraphic sequence corresponds to porphyritic and aphanitic andesitic lavas of continental origin, with intercalations of breccias and coarse-grained sandstones and some tuffaceous levels that separate the stratifications of the andesitic lavas. This formation has been assigned a Middle to Upper Jurassic age.
Rencoret Strata (JS Inf)
Formation composed of a sequence of marine limestones, conglomerates, sandstones and calcareous shales, assigned to the Lower Jurassic age, it is found outcropping in the eastern sector of Pampa Algorta.
Sierra El Cobre Formation (JS Sup)
Formation constituted by a sequence of marine limestones, conglomerates, sandstones and calcareous shales, assigned to the Lower Jurassic age, intercalated with transitional sedimentary episodes. It is found outcropping in the eastern sector of the coastal mountain range, and in the eastern portion of the San Cristobal valley.
Augusta Victoria Formation (KV)
Sequence of andesitic lava flows, volcanic breccias at the base and ignimbrites in the upper part, assigned to a Middle Cretaceous age. It is found irregularly as outcrops in most of the Pampa Blanca and Ampliación sectors.
Caleta Coloso Formation (K Inf)
Continental sedimentary sequence consisting of a finely stratified group of sandstones, arkoses, fine breccias and conglomerates. It is characterized by the lenticulosity of its strata and frequent lenses of sandstones with cross stratification and conglomerates. It is located in the intermediate terraces and basins along the central depression.





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El Way Formation (K Sup)
Marine sedimentary sequence consisting of a finely stratified group of calcareous sandstones, fossiliferous limestones, fine breccias and conglomerates. It is characterized by the lenticulosity of its strata and frequent lenses of cross-stratified sandstones and conglomerates. It is located in the intermediate terraces and basins along the central depression focused on the southern end of the area.
Intrusive Rocks
Correspond to dacites, latites, granites and diorites assigned from the Paleozoic to the Tertiary, they outcrop in isolation within the Central Depression, their major occurrence is observed in the reliefs of the Coastal Range and the Intermediate Range to the west and east of the central basin.
Unconsolidated Sedimentary Deposits
The unconsolidated sedimentary units or deposits correspond to important alluvial, alluvial-colluvial, saline and lacustrine deposits, generated by large pluvial events that occurred in the Tertiary and Pleistocene. These sedimentary filling units occupy a large part of the Central Depression area, currently forming the erosion level of the filling depression or basin in a gently undulating topography and where its depressions present saline accumulations.
The constituent materials of these deposits correspond essentially to muds and heterogeneous accumulations of gravels, sands, silts and clays that coexist with the current alluvial deposits of the ephemeral drainages developed in the basin.
Figure 6-4. Geological map at Pampa Blanca. Internal Document SQM
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6.3PROPERTY GEOLOGY
Through the collection of geological information by logging of drill holes and surface mapping, five stratified subunits have been identified within the Quaternary Unit (Qcp) (Units A to E). (Figure 6-3). These units correspond to sediments and sedimentary rocks that host the non-metallic or industrial ores of interest, i.e., iodine and nitrate. Each of the units are described below.

6.3.1 Unit A:
It is located in the upper part of the profile, and corresponds to a sulfated soil or petrogypsic saline - detrital horizon of light brown color, with an average thickness of approximately 40 cm. It consists mainly of sand and silt-sized grains, and to a lesser extent gravel-sized clast, which together define a well-cemented sulfate horizon at depth, while on the surface it is porous and friable as a result of weathering and leaching of the more soluble components, which generates a cover of fine and massive sediments approximately 20 cm thick, known as "chuca" or "chusca". This unit is characterized by exposing vertical cracks, which may or may not be filled.

6.3.2 Unit B:
It is located below unit A and corresponds to a light brown detrital sulfate soil formed by anhydrite nodules immersed in a medium to coarse sand matrix. It reaches variable thicknesses between 0.5 to 1.0 m. It is characterized by the presence of detrital-saline dikes, which are also exposed in the underlying units. This unit loses continuity in the horizontal.
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6.3.3 Unit C:
It is under unit B and corresponds to a massive sedimentary deposit of fine to medium sandstones, dark brown in color with intercalations of thicker breccia-type sediments. The thickness of this unit is variable, identifying strata from 0.5 to 2.0 m thick approximately. The sandstones are well consolidated and cemented by salts (sulfates, chlorides and nitrates). The salts, in addition to cementing the deposit, occur as enveloping clasts, filling cavities and as saline aggregates resulting from saline efflorescence.

6.3.4 Unit D:
Located below unit C, it corresponds to a massive sedimentary deposit of dark brown polymictic breccias with matrix supported sedimentary fabric. The thickness varies between 1 to 5 meters approximately, the clasts are angular to sub rounded with sizes ranging from 2 mm to 8 cm, Lithologically consisting of fragments of porphyritic andesites, amygdaloid andesites, intrusive and highly altered lithics, while the matrix consists of medium to coarse sand-sized grains. The breccia is well consolidated and cemented by salts (sulfates, chlorides and nitrates). The salts, besides cementing the deposit, occur as enveloping clasts, filling cavities and as saline aggregates resulting from saline efflorescence.

6.3.5 Unit E:
Similar to unit D, except for the sedimentary fabric and structure, unit E consists of a sedimentary deposit of dark brown polymictic conglomerate breccias with clastic supported sedimentary fabric and diffuse horizontal stratification, the clasts are sub rounded. Their granulometry varies considerably increasing the size of the clasts finding sizes greater than 10 cm and lithologically correspond to fragments of porphyritic andesites, intensely epidotized and chloritized porphyritic andesites, fragments of indeterminate altered intrusive rocks and lithics with abundant iron oxide. The deposit is highly consolidated by salts, which are observed as cement, enveloping clasts, filling cavities and as aggregates or accumulations of salts formed by saline efflorescence.

6.3.6 Unit F:
Corresponds to the igneous basement of the sedimentary sequence; in Pampa Blanca this corresponds mainly to Cretaceous volcanic rocks, andesitic to dioritic lavas, and granitic igneous bodies. The basement is scarcely mineralized; restricted to sectors where it is fractured, mineralization is found as fracture fillings.

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Figure 6-5. Stratified Units of The Superficial Unit Qcp in Pampa Blanca
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6.3.7 Pampa Blanca
The Pampa Blanca sector is part of an extensive sedimentary basin filled by a sequence of sandstones, breccias and conglomerates. The sector is affected by structures that shaped the landscape generating a morphology of raised and depressed blocks.
The sector has 3 main systems identified
Northeast - North South;
Northeast
East-West.
The temporality of the deformation indicates an activity of these systems after the formation of the deposit. The activity of the faults in the sector, as well as the subsequent action of surface runoffs were the main controllers and modelers of the geomorphology of the sector.
The lithology of this sector is constituted by (Figure 6-6)
Medium Sandstones: Medium-grained rocks of brownish color, cemented by salts, where major clasts of andesites and diorites are observed. The clasts correspond to 10-15% of the rock.
Matrix Supported Conglomerate Breccia: Matrix supported rocks, polymictic, made up of clasts of andesite and dioritic intrusive; the size of clasts varies between 2 to 4 cm. This unit shows poor sorting, cemented by salts with 25 to 30% of clasts.
Matrix Supported Brecciated Conglomerate: Matrix supported rocks, polymictic, made up of clasts of andesite, tuffs and dioritic intrusive; the size of clasts varies between 4 to 10 cm. This unit shows a better selection, cemented by salts with 35 to 40% of clasts.
Clast-Supported Conglomerate: Clast-supported rocks, polymictic, made up of clasts of andesite, tuffs, Fe oxides; silicified; the size of clasts varies between 8 to 30 cm. This unit shows a good selection, cemented by salts with 50 to 60% of clasts.

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Figure 6-6. Stratigraphic Column and Stratigraphic Cross Section in Pampa Blanca. typical sequence, formed by a Level of Fine Sandstones, Over a Sequence of Conglomerate Breccias and Conglomerates.
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The occurrence of mineralization is disseminated in the matrix and in cement. Spatially it corresponds to sub horizontal mineralized mantles reaching average thicknesses of 3.5 meters. Nitrate and iodine grades average 5.0 – 7.0% and 450 - 550 ppm respectively.




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6.3.8 Enlargement Pampa Blanca
The geomorphology of the area consists of a large central NNE basin 10 km long by 5 km wide, which is affected by drainage in an approximate north-south direction, with waterfalls to the south.
Lithologies are described in a vertical column from top to bottom:
Sun-crusted sandstones: usually associated with structures, the mineralization is in the form of cement in the matrix of these rocks. There are lateral gradations to conglomerate sandstones. This unit has a thickness of 0.3 m to 1.5 m.
Polymictic breccias: formed by subangular clasts surrounded by sandstones in a generally matrix-supported packing. Where the proportion of clasts is less than the proportion of matrix. Mineralization is found in both matrix and cement. This unit is 0.5 m to 3.0 m thick.
Clast-supported to matrix-supported conglomerates: Lithics are generally sub rounded, the clast/matrix ratio is variable between 50% to 70%. Mineralization is found filling the porosity of the rock, in the form of sub horizontal and subvertical fracture fillings and in the form of a film surrounding clasts. Laterally, gradations to conglomerate breccias are recognized. The base of this unit has not been determined.
Volcanic and intrusive units: oldest rocks in the area constituting the basement, on which the conglomerates are deposited. These units are locally mineralized in some sectors as filler in fractures and porosities of the rocks.

6.3.9 Blanco Encalada
This area is part of an extensive sedimentary basin filled by a sequence of sandstones, breccias and conglomerates. The sector is affected by structures that shaped the landscape generating a morphology of raised and depressed blocks.
The lithologies present in the area from top to bottom are as follows:
Medium Sandstones: Medium-grained rocks of brownish color, cemented by salts, where major clasts of andesites and diorites are observed. The clasts correspond to 10-15% of the rock.
Matrix Supported Conglomerate Breccia: Matrix supported rocks, polymictic, made up of clasts of andesite and dioritic intrusive; the size of clasts varies between 2 to 4 cm. This unit shows poor sorting, cemented by salts with 25 to 30% of clasts.
Matrix Supported Breccia Conglomerate: Matrix supported rocks, polymictic, composed of clasts of andesite, tuffs and dioritic intrusive; the size of clasts varies between 4 to 10 cm.
Clast-Supported Conglomerate: Clast-supported rocks, polymictic, made up of clasts of andesite, tuffs, Fe oxides; silicified; the size of clasts varies between 8 to 30 cm.
The occurrence of mineralization is disseminated in the matrix and in cement. Spatially it corresponds to sub horizontal mineralized mantos that reach average thicknesses of 3.0 meters with average Nitrate and Iodine grades of 7.0 – 7.5% and 400 – 450 ppm respectively.

6.4MINERALIZATION
Mineralization is concentrated as saline cement in sandstone, breccia and conglomerate units, where the main ore is iodine and nitrate. As a result of geological activity over time (volcanism, weathering, faulting) the deposits can be found in:
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Continuous Mantles: Continuous mineralization throughout the stratigraphic level, sandstones and breccias with mineralization in matrix and cement clasts; presenting variable thicknesses between 2.0 to 4.0 meters. An enrichment in nitrate grades is observed at greater thickness, compared to the iodine ore which is diluted at depth. These mantles are cut by the so-called "sand dykes", fractures filled with fine mineralized material, mainly sandstones of high compaction. These structures are observed along the entire mineralized mantle and at the contact between stratification planes.
Thin Salt Crusts and Superficial Caliche ("caliche in the sun"): Discontinuous mineralization, associated to sectors contiguous to saline and/or evaporite deposits. This occurrence generates sectors of high grade and low thickness (0.5 to 1.2 m), associated to fine sandstones of high competence; we can find concentrations over 1,500 ppm of iodine and 20% of Nitrate.
"Stacked" Caliche: Mineralized caliches immersed in leached sedimentary rocks. This type of occurrence is found in sectors with a high degree of leaching (associated to alluvial fans), which produces a loss of competence of the host rock, generating poor quality mantles with more competent accumulations of mineralized caliches. The thickness of these levels or potatoes is variable, reaching averages of 2.0 m. The grades of these caliches are low, being considered low quality caliches.
The main agents controlling the occurrence of mineralization are the product of geological activity over time:
Subway and surface runoff (produce vertical and horizontal remobilization of salts, causing zones of mineral concentration within the patches).
Magmatic activity (through geologic time will continue to contribute hydrothermal solutions that will cause precipitation and remobilization of salts).
Chemical weathering; mainly by surface waters that through geologic time have produced remobilization of salts, until finding the current deposits.
Faults/Structures; salt concentrations (Nitratine) have been identified in fracture fillings between sedimentary levels (clastic dikes) and in recent fault scarps. The mineralization associated with structure / faults is massive, high grade and low thickness.
The mineralogical association identified corresponds mainly to soluble sulfates of Na - K, less soluble sulfates of Ca, Chlorides, Nitrates and Iodates.
Within the mineral species of interest, for Nitrates; Nitratine (NaNO3) - KNO3 (Potassium Nitrate); Hectorfloresite, Lautarite, Bruggenite as iodates.
Table 6-7 presents a summary of the mineralogy of the Pampa Blanca Property. The number of samples included in the database on which the table is based are indicated by the “n = “value in the table header. Pampa Blanca Sector IV has by far the greatest number of samples with n=23. The mineral recorded are indicated as percentage. The table uses the following color coding to indicate the percentage content by mass of dry sample of each mineral of interest:
Red fill indicates that the mineral accounts for 10% or greater of the mass of the dry samples.
Orange fill indicates that the mineral accounts for between 5% and 10% of the mass of the dry samples.
Yellow fill indicates that the mineral accounts for between 1% and 5% of the mass of the dry samples.
In a cell with no color fill indicates that the mineral of interest accounts for less than 1% of the mass of the dry samples.


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Table 6-7. Mineralogy of Pampa Blanca Caliche.
GroupMineral SpeciesFormulaSector IV (n=23)Sector V (n=23)
NitratesNitratine
NaNO3
4.9%11.1%
Niter
KNO3
0.6%
Humberstonite
Na7K3Mg2(SO4)6(NO3)2·6H2O
1.0%
IodatesDarapskite
Na3(SO4)(NO3)·H2O
1.3%
Lautarite
Ca(IO3)2
0.5%
Bruggenite
NaCaAl2(SO4)2(OH)6⋅3H2O
0.9%2.2%
Fuenzalidaite
Na3(SO4)(OH)⋅4H2O
0.5%
Hectorfloresite
Na2K2Fe22+Fe63+Si6O24(OH)6
0.6%0.7%
SulfatesBassanite
CaSO₄.1/2H₂O
0.7%
Kieserite
MgSO4⋅H2O
1.4%3.0%
Polyhalite
K2Ca2Mg(SO4)4⋅2H2O
5.5%11.2%
Rostite
Na2Ca3(SO4)4⋅24H2O
2.3%
Gypsum
CaSO4⋅2H2O
0.6%
Anhydrite
CaSO4
5.5%2.6%
Glauberite
Na2Ca(SO4)2
2.6%3.3%
Loweite
Ca3Al4(OH)12⋅2H2O
3.1%5.3%
Hexahydrite
MgSO4⋅6H2O
1.0%
Blodite
Na2Mg(SO4)2⋅4H2O
1.2%1.4%
ChloridesHaliteNaCl1.7%7.3%
ClaysPaligorskite
(Mg,Al)2Si4O10(OH)⋅4H2O
1.5%3.4%
Illite
K0.65Al2[Si4O10](OH)2⋅nH2O
2.1%
Kaolinite
Al2Si2O5(OH)4
2.3%
Montmorillonite
(Na,Ca)0.3(Al,Mg)2Si4O10(OH)2
0.7%
LensesMuscovite
KFe23+(AlSi3O10)(OH)2
4.2%2.1%
Clinochlorite
(Fe,Mg)5Al(Si3AlO10)(OH)8
1.0%
Biotite
K(Mg,Fe 2+)3[AlSi3O10(OH,F)]
0.7%
SilicatesOrthoclase
KAlSi3O8
1.8%4.9%
Quartz
SiO2
4.0%7.1%
Albite
(Ca-Na)Al2Si2O8
10.2%15.0%
Sanidine
KAlSi3O8
8.3%
Phlogopite
KMg3(AlSi3O10)(OH)2
0.5%
Pargasite
Ca2Mg4Al(Si7TiO22)(OH)2
3.5%3.9%
Anorthite
NaAlSi3O8
13.7%14.1%
Hornblende
Ca2Mg5Si8O22(OH)2
1.5%
Edenite
NaCa2Mg5(AlSi7O22)(OH)2
0.9%1.2%
Wollastonite
CaSiO3
2.0%
ZeolitesStellerite
Ca4(Al8Si28O72)⋅30H2O
1.9%


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6.5DEPOSIT TYPES

6.5.1 Genesis of Caliche Deposits
The Hyperarid core of the Atacama Desert experiences negligible precipitation (<2 mm per year) (Figure 6-7). The estimated ages for the onset of hyperaridity range from the Late Paleogene through the Pleistocene, although the exact timing is still debated. Geochronological, sedimentological, and geomorphological evidence point to a long history of semi-arid climate from ~45 Ma (Middle Eocene) to 15 Ma (Middle Miocene), followed by a stepwise aridification. The geological evolution in the zone shows strong feedback between climate and tectonics that is specific to the way that the rapidly uplifting Central Andean convergent margin (Schildgen and Hoke 2018 this issue) experienced pronounced desiccation between ~20 Ma and 10 Ma (i.e. a decrease in precipitation from >200 mm/y down to <20 mm/y). This led to the development of an exclusively endorheic drainage system an enclosed basin system that receives water but does not have any way for that water to flow out to other bodies of water that is recharged in the High Andes, where increased elevation creates favorable conditions for increased groundwater flow and mineral precipitation towards the Central Valley (Pérez-Fodich et al. 2014).
The sum of these tectonic, climatic, and hydrologic characteristics has shaped, in a singular manner, the supergene metallogenesis of the Atacama Desert. The preservation of these specific supergene deposits is due to the hyperaridity that is the principal factor in this region becoming the world’s greatest producer of commodities such as nitrate, iodine, copper, and lithium (Reich et al, 2018).
Figure 6-7. Maps of the Central Andes of South America (A) Digital Elevation Map with Principal Morphotectonic provinces of the Southern Central Andes labelled. The red rectangle shows the area depicted in Figure 1B. (B) Map of the Nitrate Deposits of the Atacama
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6.5.2 Local Mineral Deposit
In the Norte Grande region of Chile (18°-27°South Lat.) the presence of salts has a wide distribution in soils, sedimentary sequences, evaporitic basins, underground and surface waters and in dynamic fogs. The majority presence of chlorides, sulfates, carbonates, borates, and other rather unusual salts in Nature such as nitrates, iodates, chromates, dichromats, chlorates and perchlorates are recognized.
7EXPLORATION
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Ongoing exploration is conducted by SQM with primary purpose of supporting mine operations and increasing estimated Mineral Resources. The exploration strategy is focused on have preliminary background information on the tonnage and grade of the ore bodies and will be the basis for decision making for the next Recategorization campaigns. Exploration work was completed by mine personnel.
7.1SURFACE SAMPLES
SQM does not collect surface samples for effect of exploration.
7.2TOPOGRAPHIC SURVEY
Detailed topographic mapping was created in the different sectors of Pampa Blanca by aerial photography, using an unmanned aircraft operated by remote control, Wingtra One (Figure 7-1); equipment with 61 Mega pixels resolution, maximum flight altitude 600 m, flight autonomy 55 minutes. The accuracy in the survey is 5 to 2 cm.
The measurement was contracted to STG since 2015.
Figure 7-1. Wingtra One fixed-wing aircraft
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Prior to 2015, the topography survey was done by data measurement profiles every 25 meters; these profiles were done by walking and collecting information from points as the land surveyor made the profile. With this information, the corresponding interpolations were generated to obtain sector surfaces and contour lines.
7.3DRILLING METHODS AND RESULTS
The Pampa Blanca geologic and drill hole database included 20,952 holes that represented 125,286 m of drilling. Table 7-1 summarizes the drilling by sector. Figure 7-2 shows the drill hole locations. As for the type of drilling used, it corresponds to RC holes, with a maximum depth of 7 meters. All the Pampa Blanca drilling was done with vertical holes.

Table 7-1. Detail of the Number of Drill Holes and Total Meters Drilled by sector in Pampa Blanca Properties

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SectorGridN° of Drill HolesTotal metersThickness (m)Core Recover
Pampa Blanca 32001791,0746.091
Pampa Blanca 450-100-100T-200-40010,39761,7636.096
Pampa Blanca 550-100-200-4003,97223,8236.082
Blanco Encalada200-400-8004042,6266.5No Data
Pampa Blanca Expansion50-200-4006,00036,0006.091
20,952125,286

The standard exploration work procedures as described by SQM are summarized in the following sections. All exploration activities consider the importance of health and safety within all mining activities. The exploration procedures are regularly revised and improved.
The drilling campaigns were carried out according to the resource projection priorities of the Superintendence of Mineral Resources and LP Planning. Subsequently, this prospecting plan was presented to the respective VPs to ratify if they comply with the reserve projections to be planned, if they do not coincide, the prospecting plan is modified.
Drilling at Pampa Blanca were completed with prospecting grids of 400 x 400 m, 200 x 200 m, 100 x 100 m, 100 locked and 50 x 50 m.
The resources measured in Pampa Blanca are reduced to mesh 50; however, the current recategorization to measure resources is being done in M100T.
Figure 7-2. Pampa Blanca Drill hole location map
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Grid > 400 m
Areas that have been recognized and that present some mineralization potential are initially prospected in wide mesh reverse air holes, generally greater than 400 m with variable depths of 6 to 8 m depending on the depth at which the ore is encountered. In consideration of the type of mesh and the fact that the estimations of tonnage and grades are affected in accuracy, this resource is defined as a Hypotheticals and Speculative Resources, exploration target grid > 400 m.
400 m Grid
Once the Inferred sectors with expectations are identified, 400 x 400 m drill hole grids are carried out. In areas of recognized presence of caliche or areas where 400 x 400 m grid drilling is accompanied by localized closer spaced drilling that confirms the continuity of mineralization, the 400 m grid drilling provides a reasonable level of confidence and therefore define dimensions, thickness, tonnages and grades of the mineralized bodies, used for defining exploration targets and future development. The information obtained is complemented by surface geology and the definition of geological units. In other cases when there is no reasonable level of confidence the 400 x 400 m drill hole grid will be defined as a Potential Resource.
200 m Grid
Subsequently, the potential sectors are redefined, and the 200 x 200 m drill hole grid are carried out, which in this case allows to delimit, with a significant level of confidence, the dimensions, power, tonnage and grades of the mineralized bodies as well as the continuity of the mineralization. At this stage, detailed geology is initiated, the definition of geological units on surface continues to be complemented and sectors are defined to carry out geometallurgical assays. This area is used to estimated Indicated Mineral Resources.
100 m, 100T and 50 m Grid
The 50 x 50 m, 100x 100 m and 100T ~ 100x50 m drill hole grid allows to delimit with a significant level of confidence (amount of information associated to the drilling grid) the dimensions, powers, tonnages and grades of the mineralized bodies as well as the continuity of the mineralization. The definition of geological units and collect information on geometallurgical assays from the pilot plants depending on the prospecting site is then continued. This area is used to estimate Measured Mineral Resources.
























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Figure 7-3. Iso Iodine Pampa Blanca

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The results of the drilling campaigns in the Pampa Blanca can be seen in Figure 7-3, where it is highlighted in red the sectors with iodine greater than 450 ppm, in magenta the iodine between 400 - 450 ppm; in blue the iodine between 350 - 400 ppm; in green the iodine between 300 – 350 ppm and in yellow the iodine less than 300 ppm.






7.3.1 2024 Campaigns.
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SQM has an ongoing program of exploration, recategorization and resource evaluation in the areas surrounding the Pampa Blanca mine, which is currently in operation. SQM has performed reconnaissance drilling at 400 m spacing or lower in 18.5% of the area covered by its mining properties over the areas with caliche interest. (Table 7-2)
In 2024, no recategorization projects of Mineral Resources were carried out in Pampa Blanca and its surroundings.

7.3.2 Exploration Drill Sample Recovery
Core recovery has been calculated for all RC holes completed to date. In historical campaigns, the recovery was lower due to the type of drilling rig used.
It should be noted that the recoveries are above 80%, a value that fluctuates in direct relation to the degree of competence of the rock to be drilled. Table 7-2 details the recovery percentages by sector in Pampa Blanca.

Table 7-2. Recovery Percentages at Pampa Blanca by Sectors
SectorGridN° of Drill HolesTotal metersThickness (m)Core Recover
Pampa Blanca 32001791,0746.091
Pampa Blanca 450-100-100T-200-40010,39761,7636.096
Pampa Blanca 550-100-200-4003,97223,8236.082
Blanco Encalada200-400-8004042,6266.5No Data
Pampa Blanca Expansion50-200-4006,00036,0006.091
20,952125,286


7.3.3 Exploration Drill Hole Logging
For all the samples drill hole logging was carried out by SQM geologist, which was done in the field. Logging procedures used documented protocols. Geology logging recorded information about rock type, mineralogy, alteration and geomechanics.
The logging process included the following steps:
- Measurement of the “destace” and drill hole using a tool graduated in cm.
- Mapping of cutting (RC) and/or drill hole cores (DDH), defining their color, lithology, type and intensity of alteration and/or mineralization.
- Determination of geomechanical units a Leached, smooth, rough and intercalations.
The information is recorded digitally with a Tablet and/or computer, using a predefined format with control system and data validation in Acquire.
The Logging Geologist was responsible for:
- Generate geological data of the highest possible quality and internal consistency, using established procedures and employing System in Acquire.
- Locate and verify information of work to be mapped.
- Execute geomechanical and lithological drill hole mapping procedures.
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7.3.4 Exploration Drill Hole Location of Data Points
The process of measuring the coordinates of drill holes collars was performed, in 2 stages. Prior to the drilling of the drill holes, the geology area generates a plan and list with the number of drill holes by Acquire, to be marked and coordinates to the personnel of the external contractor of the STG company. A Land surveyor measured the point in the field and identifies the point with a wooden stake and an identification card with contain barcode with information of number of drill hole recommended, coordinates and elevation.
Holes are surveyed, after drilling, with GNSS equipment, for subsequent processing by specialized software with all the required information. Once the complete campaign is finished, the surveyed data was reviewed, and a list was sent with the drill id information and its coordinates.
Collar coordinates were entered into Microsoft® Excel sheets and later aggregated into a final database in Acquire by personnel from SQM.
At the completion of drilling, the drill casing was removed, and the drill collars were marked with a permanent concrete monument with the drill hole name recorded on a metal tag on the monument.

7.3.5 Qualified Person’s Statement on Exploration Drilling
The Qualified Person believes that the selection of sampling grids of gradually decreasing spacing as Mineral Resources areas are upgrades from Inferred to Measured Mineral Resources and as they are further converted to Proven, and Probable Mineral Reserves where production plans have been applied, is appropriate and consistent with good business practices for caliche mining. The level of detail in data collection is appropriate for the geology and mining method of these deposits.

8SAMPLE PREPARATION, ANALYSIS AND SECURITY
8.1SITE SAMPLE PREPARATION METHODS AND SECURITY

Analytical samples informing Nueva Victoria Mineral Resources were prepared and assayed at the Iris plant and Internal Laboratory located in city of Antofagasta.

All sampling was completed by the external operators. Based on review of the procedures during the site visit and subsequent review of the data, it is the opinion of the QP that the measures taken to ensure sample representativeness were reasonable for estimating Mineral Resources.

8.1.1 RC Drilling

The RC drilling is focused on collecting lithological and grade data of chemical variables from the “Caliche mantle”. RC Drilling was carried out with a 5 ¼ inch diameter by an external company "Perforations RMuñoz" under the supervision of SQM. SQM designed the drilling campaigns and points of interest to obtain new information on caliche mantle grades.

Once the drilling point was designated, the positioning of the drilling rig was surveyed, and the drill rig was set up on the surveyed drill hole location, continue with the drilling (Figure 8-1 A, B y C). At the beginning of each drill hole, the drilling point was cleaned or uncovered, eliminating the soft overburden, or chusca, with a backhoe.

Samples were collected from the cyclone at continuous 50 cm intervals in plastic bags. The samples were weighed and quartered at the platform. A cutting sample was taken and left on the floor as a control sample. The sample bag was tied, and a number card was inserted. (Figure 8-1 D).

Figure 8-1. A) Drilling Point Marking B) Drill Rig Positioning C) RC Drilling D) RC Samples at Platform
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Samples were transported by truck to the plant for mechanical preparation and chemical analysis. Samples were unloaded from the truck in the correct correlative order and positioned on Pallets supplied by the plant manager (Figure 8-2).

Figure 8-2. A) Transportation Truck. B) Pallets with RC Samples
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8.1.2 Sample Preparation
Mechanical sample preparation was carried out by Pilot Plant Iris V7 located at Nueva Victoria. Sample preparation includes:
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Division of the sample in a cone splitter into 2 parts, one of which corresponds to discard. The sample obtained should weigh between 1.0 to 1.8 kg.
Drying of the sample in case of humidity.
Sample size reduction using cone crushers to produce an approximately 800 gr sample passing a number 8 mesh (-#8).
Division of the sample in a Riffle cutter of 12 slots of ½" each. The sample is separated in 2, one of them corresponds to rejection and the other sample must weigh at least 500 gr.
Sample pulverizing.
Packaging and labeling, generating 2 bags of samples, one will be for the composites in which 200 gr are required (original) and the other will be for the laboratory, in which 100 gr are required (sample) (Figure 8-4)
Insertion points for quality control samples in the sample stream were determined. Standards samples were incorporated every 20 samples, including the first sample. Samples were shipped in boxes containing a maximum of 63 samples (weighing approximately 15 kg) to the Caliche Iodine Internal laboratory.

Figure 8-3. Sample Preparation Flow Diagram


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Figure 8-4. A) Sample Division B) Cone Crusher C) Riffle Cutter D) Sample Pulverizing E) Packaging

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8.2LABORATORIES, ASSAYING AND ANALYTICAL PROCEDURES
Chemical analysis for NO3 and iodine was performed at the Caliche Iodine laboratory, located in Antofagasta, which is ISO 9001:2015 certified in shippable iodine, replicated in caliche and drill holes.
The Caliche Iodine Laboratory has capacity to analyze 500 samples/day for nitrate and iodine analysis. Sample handling, from receipt to analysis, is performed in 3 areas:
Receiving area.
Nitrate area.
Iodine Area.
Nitrate analysis was performed by UV-Visible Molecular Absorption Spectroscopy. The minimum concentration entered the Laboratory Information Management System (LIMS) was 1.0%, the result was expressed in g/L of NaNO3. Iodine analysis was performed by Redox volumetric. The minimum concentration reported to the LIMS system was 0.005 %.
8.3RESULTS, QC PROCEDURES AND QA ACTIONS

8.3.1 Laboratory quality control
To validate the results of the laboratory analysis, the following control measures were carried out (Figure 8-5).
Iodine:
Prepare a reference standard.
Use of secondary reference material.
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Measure the reference standard and the reagent blank to ensure the quality of the reagents used.
Every 5 samples a QC prepared with a Caliche of known concentration
Of the obtained result should not exceed 2% of the nominal value of the QC, otherwise the variables should be revised, and the analysis of the batch should start from the beginning.
Nitrate:
Analyze at the beginning of the sample set a standard solution.
Every 5 samples a QC prepared with a Caliche of known concentration, the variation of the obtained result should not exceed 5% of the nominal value of the QC, otherwise the variables should be revised, and the analysis of the batch should start from the beginning.

Figure 8-5. Flow Chart for Approval of Laboratory Chemical Analysis Results
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8.3.2 Quality Control and Quality Assurance Programs (Qa-Qc)

Qa/Qc programs were typically set in place to ensure the reliability and assurance of the exploration data. They include written field procedures of aspects such as drilling, surveying, sampling, and assaying, data management, and database integrity.

The quality control program aims to ensure the quality of the data from the drilling campaigns so that the grade data entered into the estimation databases have sufficient precision and accuracy to be considered reliable. For this purpose, blind control samples are inserted into batches, which consist of racks of 70 samples. The insertion templates A and B are generated and controlled by the AcQuire software, which distributes the controls as follows, adding 16.7%, including high-grade standards, low-grade standards, blanks (known and certified values), and duplicate samples (Table 8-1).

Table 8-1. Quantity and Type of Control for Insertion.
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SampleTemplate A% Template ATemplate B% Template B
Samples Primary60100%60100%
DUPG (Coarse Duplicate)11.7%11.7%
DUPP (Fine Duplicate)23.3%23.3%
STDA (High Grade Standard)23.3%11.7%
STDB (Low Grade Standard)11.7%23.3%
DUP (Duplicate Field)11.7%11.7%
BK (Blank)35%35%

The number of controls entered is directly proportional to the number of samples per box, according to the formula:

STD (A, B, BK & DUP, DUPG, DUPP) = (Template / Number of samples per box) *100

To prepare the boxes with quality controls, trained technical personnel is used for sample handling and the use of the AcQuire software. Their responsibility is to ensure proper sample handling to avoid contamination and correct insertion of all controls, ensuring that the samples are numbered sequentially. Once this is done, the box is sealed for transportation to the SQM laboratory. The AcQuire system uses a barcode system with digital reading, which minimizes human error, as it does not allow the process to continue if the barcode codes are not sequential. Additionally, the box that transports the samples has encoding and a QR code to ensure traceability.

Figure 8-6. Creation of boxes, indicating samples with barcodes.

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These batches are analyzed in the laboratory in order to quantify the precision, accuracy and contamination of the process as detailed below:

-Precision: It is quantified through the percentage of failures of duplicate pairs. The acceptability limit is no more than 10% of failures that exceed 3 times the practical detection limit.

-Accuracy: With the results of the analysis of standards, the relative bias and the coefficient of variation are calculated and the process control is also analyzed through a control chart. The acceptability ranges are a maximum of 5% bias (positive or negative) with a coefficient of variation of no more than 5% and it is recommended to investigate when the processes go out of control, whether due to gross, analytical, systematic or other errors. A sample is defined as being out of control when it exceeds 3 standard deviations, or if 2 or more consecutive samples exceed 2 standard deviations.

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-Contamination: Fine white samples must not exceed 5% with a value exceeding 3 times the practical detection limit of the laboratory. If these deliver results outside the established parameters, the batch (rack) is rejected, and the root cause of the problem is investigated to subsequently reanalyze the racks involved.

The AcQuire and LIMS systems function as our databases to obtain information and perform the tracking of all samples, optimizing the time for results and their reliability regarding traceability.

8.3.2.1 QAQC Program Results

The results of the Qa-Qc program for the Pampa Blanca Sector from 2023 to end 2024. The results of the QAQC program are delivered in detail for each pampa that results were obtained.

Standards
Table 8-2 details a summary table of control results for each pampa.

Table 8-2. Summary Table of Results of Controls (Standard) – Pampa Blanca

SectorSTDMVElementUnitAverageSamplesOCSOCS (%)Bias (%)CV (%)
Pampa Blanca
STD_A_1
499
I2
ppm
499.02
82
1
1.22
-0.27
3.80
Pampa Blanca
STD_A_1
5.93
NaNO3
%
5.78
82
2
2.44
-2.53
2.89
Pampa Blanca
STD_B_1
250
I2
ppm
248.52
81
1
1.23
-0.95
5.66
Pampa Blanca
STD_B_2
2.76
NaNO3
%
2.63
81
3
3.70
-4.94
5.87


Pampa Blanca
The following figures provide the results for accuracy graphs in Pampa Blanca for the iodine (Figure 8.7) and nitrate (Figure 8.8) variables.

Figure 8-7. STD A-1 and B-1 Iodine Accuracy Evaluation (499 ppm and 250 ppm).

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Figure 8-8. STD A-1 and B-1 Nitrate Accuracy Evaluation (5.93 % and 2.76 %).

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Duplicates

Pampa Blanca

Coarse and Fines Duplicates

In the results of duplicates for iodine and nitrate in coarse (Table 8-3) and pulp (Table 8-4) for pampa Hermosa, the following accuracy results were observed.

Table 8-3. Summary Table of Results Duplicates Coarse – Pampa Blanca

StatisticiansNitrate Grade %DifferenceStatisticiansIodine Grade ppmDifference
OriginalCheckOriginal - CheckOriginalCheckOriginal - Check
Number
54
54
Number
54
54
Mean
3.49
3.32
0.17
Mean
226.67
216.30
10.4
Stand. Deviation
3.57
2.92
0.65
Stand. Deviation
268.4
218.1
50.2
% Difference
4.83
% Difference
4.58
Minimum
1
1
Minimum
50
50
Percentile 25
1.2
1.3
Percentile 25
80
100
Median
2.35
1.95
Median
150
150
Percentile 75
4.6
4.3
Percentile 75
250
240
Maximum
20.5
14
Maximum
1680
1300
Correlation Index
0.93
Correlation Index
0.95


Table 8-4. Summary Table of Results Duplicates Pulp – Pampa Blanca

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StatisticiansNitrate Grade %DifferenceStatisticiansIodine Grade ppmDifference
OriginalCheckOriginal - CheckOriginalCheckOriginal - Check
Number
167
167
Number
168
168
Mean
2.68
2.73
-0.05
Mean
203.04
202.02
1.0
Stand. Deviation
2.33
2.39
-0.052
Stand. Deviation
180.9
180.6
0.3
% Difference
-1.97
% Difference
0.50
Minimum
1
1
Minimum
50
50
Percentile 25
1.2
1.2
Percentile 25
90
90
Median
2
1.9
Median
140
140
Percentile 75
3
3.2
Percentile 75
250
240
Maximum
15.1
14.9
Maximum
1,2701,290
Correlation Index
0.948
Correlation Index
0.990


Blanks

Contamination in quality control is indicated by controls of white samples, below is a summary table of the results of blanks controls in the pampas of Nueva Victoria (Figure 8-5).

Table 8-5. Summary Table of Results Blanks – Nueva Victoria

Sector
I2
NO3
SamplesAverageDesv StandOCS%OCSSamplesAverageDesv StandOCS%OCS
Pampa Blanca
56
58.0
12.1
0
0.0%
56
1.0
0.1
0
0.0%


The following figures correspond to the 4 pampas that have the highest number of white control samples in Pampa Blanca (Figure 8-9).

Figure 8-9. Figure of Blanks (I2 and Nitrate) – Pampa Blanca

figure8-9.jpg


8.3.3 Sample Security

SQM maintains strict control over sampling, mechanical sample preparation and chemical analysis. In each of the stages, the safety and chain of custody of the samples was safeguarded, using protocols that describe the steps to be followed for this purpose. All these controls are managed and controlled through the Acquire platform, in process of implement by SQM since Q3 2022, according to the follow sections.

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This section highlights your current processes and procedures and introduces data management processes recommended for deployment in GIM Suite.

The following workflow architecture demonstrates the data flow and object requirements of GIM Suite.

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8.3.3.1    Planning RC Drilling
The drilling are planned by the geology area using modeling software, which generates an Excel file containing a previous identification of the drilling, which will later be modified for the final identification, along with the east and north coordinates and the planned depth are also indicated. This planning drilling is import task into Arena should allow the user to import the planned drill hole data from the file. Coordinates must be entered in PSAD56. The object must enter the status of the drilling as Planned at the time of import, as well as store the identification of the probing planning in a virtual field. Template file for importing planned drillholes.
Task in "Arena" that will show the information of the planned drilling.

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8.3.3.2     Header
In general, a drilling plan can take up to 30 thousand meters of drilling or more, depending on the objectives that are in the year, between 4 thousand and 5 thousand meters are drilled in the month for each drilling rig, the contractor company executes the drilling and monthly delivers to the geology area the file with the information taken in the field. Some drilling that was ultimately planned may not be executed due to poor facility conditions.

Import Final Drills: Object of import in Acquire 4 that allows the user to import the collar data of the final drilling, also considering the import of the original samples and their respective duplicates of terrain. Due to the geology having the same stretch as the geological mapping, it is indicated to occupy the compound of blastholes for the storage of this data.

Data Capture Collar: Data Capture of Sand based on Blastholes, which will be used in the field for the capture of collar and sample data, where you must indicate the sounding that the duplicate ground sample can take, the section of the first sample will be entered manually by user, once it must consider the highlight section of the drilling. The subsequent sections may be indicated automatically by the application, considering as a protocol that the samples original is usually 50 cm in size. The correlative of the samples will continue to be controlled by the checkbooks occupied in land, the user must manually enter the correlative of the first sample taken in the field, the correlative of the subsequent samples will be entered automatically by the application. In this Data Capture, the user can also change the status of the probe as Canceled, thus identifying the drilling that was not executed in the field.

Import Final Coordinates: With this importer object of the Acquire 4, the user will enter the final coordinates data of the drilling, the importer will validate if the final coordinates contain a difference in meters greater than 10% in relation to the planned coordinates, indicating a message to the user at the time of data entry.

Consult probing collar: Task in "Arena" that will show the information of the necklace of the soundings.

Dashboard Planned vs Executed Meters: Dashboard in Sand that presents a graph and grid with information of the planned meters on the perforated meters, thus providing additional information to control the meters of the drilling campaigns. The data can be filtered by date of execution of the drilling and sector of the mine.

Choose Sample Correlates: Data Entry object in Acquire 4 that will allow the user to enter a range of correlative samples making it possible to choose which samples will be printed the labels. The object must indicate the initial SAMPLE ID to be printed, so that user error is avoided.

Sample Label Report: Report in Acquire 4 that allows the user to print sample labels in the format of the checkbook, the report will be applied on an A4 or Letter size paper, considering that the printing will be made on a cardboard paper. The label will have the barcode with the identification of each sample, thus enabling the user to read the barcode with the tablet camera when entering the identification of the first sample.

8.3.3.3    Geological mapping
In the geological mapping, data on lithology, clast, clays, color, sulfate, salt crust, anhydrite crust, sulfate destace, percentage of clast and observation are captured.

Geological Mapping: Data capture in "Arena" that allows the user to perform the geological mapping of the drilling, this tool must allow the user to perform the mapping in the field so that it is not connected to the mine network. The task will occupy Blastholes as the task type.

Import Geologic Mapping: Importer in "Arena" that allows to enter the geological mapping data carried out in the field.

Geomechanics Mapping: Data capture in "Arena" where the geomechanical data of the drilling will be captured. For the data not related to the samples, this data capture must be of the Drillholes type.

Import Geomechanics Mapping: Importer in "Arena" that allows to enter the geomechanical mapping data carried out in the field.

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Consult Geology of Drilling: Task in "Arena" that will show the information of the geology of the drilling.

Consult Geomechanics of Drilling: Task in "Arena" that will show the information of the geomechanics of the drilling.

8.3.3.4    Dispatch of samples for mechanical preparation
Create dispatch order for Physical Sample Preparation: In this object the user can generate the order of dispatch of samples for physical preparation. Create a correlative and identifier for the office number. Example for identification. F2022-0001 where, F = Physical dispatch prefix, 2022 = Year of Shipment, 0001 = Correlative controller per year.

Print dispatch order for Physical Sample Preparation: Object that will allow to execute the printing of the report of shipment order to physical preparation.

Physical Office Reception: Script object in Acquire that allows the user to indicate the samples received in the pilot plant, the object must be filtered by physical dispatch number where it will make available the samples associated with this dispatch, thus enabling the user to select the samples and indicate in the system that these samples were received. The object must indicate and automatically create the pulp samples indicating the position where each one was generated.

Consult Drilling Dispatch to Preparation: Task in Sand that will show the information of the dispatch of the samples of the drilling that were sent to mechanical preparation.

Consult Pulp Samples: Task in Arena that will have the information of the pulp samples in a grid of data associated with the number of the physical dispatch received by the pilot plant.
In the drilling stage, before drilling begins, the drill rod was marked to indicate the distance for sampling. The drilling machine was equipped with a cyclone to slow down the particle velocity, under it, a bag is placed to collect the samples.

The collected sample from the cyclone is carefully stored in a plastic bag, then it was identified with a sequential card with a barcode and tied. The Supervisor oversaw requesting a revision to a determined sample of the drilling (coarse sample), originating another sample and of noting the weights obtained in the balance for each cut sample. This data collection is done through the Acquire platform.
The samples were loaded daily onto the truck that will transport them to the sample plant, the following steps are followed:
SQM Supervisor delivers a dispatch guide with the drill holes and the total number of samples to be collected and also mentions to the person in charge of the sample plant, the number of samples and the number of samples without recovery, if any. This dispatch guide is generated for Acquire platform.
Samples are loaded sequentially according to the drilling and unloaded in the same way.
Upon arrival at the plant, the corresponding permit must be requested from the area manager, who will provide an unloading guideline, which contemplates how the samples should be positioned on the pallets.
The pallets with samples are moved to the sample preparation area from their storage place to the place where the Cone Splitter is located.
During all stages of sample preparation, special care was taken to maintain the identification of the samples and to clean the equipment after use. The samples already packed and labeled were collected following the instructions for filling boxes of “caliche” samples, respecting the correlative order of the samples, the order in which they must be deposited in the box and the quantity of samples according to the capacity of the box.
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The trays were labeled indicating the corresponding information and date (Figure 8-11) are then transferred to the storage place at Testigoteca (core Warehouse) Iris and Testigoteca TEA located at Nueva Victoria (Figure 8-12), either transitory or final, after being sent to the laboratory.

Figure 8-11. A) Samples Storage B) Drill Hole and Samples Labeling
figure8-11.jpg
Figure 8-12. Iris – TEA Warehouse at Nueva Victoria
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Assay samples were collected by appropriately qualified staff at the laboratories. The analysis results of the samples were reported by the specialty analyst to the LIMS software system, integrated to platform Acquire.
Automatically LIMS triggering an e-mail to the users and only to those who are authorized to send the information.
8.4OPINION OF ADEQUACY
In the QP's opinion, sample preparation, sample safety, and analytical procedures used by SQM in Pampa Blanca, follow industry standards with no relevant issues that suggest insufficiency. SQM has detailed procedures that allow for the viable execution of the necessary activities, both in the field and in the laboratory, for an adequate assurance of the results.








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9DATA VERIFICATION
9.1PROCEDURES
Verification by the QP focuses on drilling, sample collection, handling and quality control procedures, geological mapping of drill cores and cuttings, and analytical and quality assurance laboratory procedures. Based on the review of SQM's procedures and standards, the protocols are considered adequate to guarantee the quality of the data obtained from the drilling campaigns and laboratory analysis.
9.2DATA MANAGEMENT
Using the drilling, the recognition of the deposit is carried out in depth and to this is used prospecting grids 400 x 400 m, 200 x 200 m, 100 x 100 m, 100T and 50 x 50 m. Depend on the size of drillhole grid, the Resources are estimated by different interpolations methods (for details see 1.3 Mineral Resources Statement).
The samples obtained from these reverse air drilling campaigns are sent to the internal laboratory of SQM who have quality control standards regarding its mechanical and chemical treatment. QA-QC analyzes are performed on control samples in all prospecting grid (400 x 400 m, 200 x 200 m, 100 x 100; 100T and 50 x 50m). This QA-QC consists of the analysis of NaNO3 and Iodine concentrations in duplicate vs. original (or primary) samples.
9.3TECHNICAL PROCEDURES
The QP reviewed data collection procedures, associated to drilling, sample handling and laboratory analysis. The set of procedures seek to establish a technical and security standard that allows field and lab data to be optimally obtained, while guaranteeing worker’s safety.
9.4QUALITY CONTROL PROCEDURES
The competent person indicates that in SQM Quality Control ensures the monitoring of samples accurately from the preparation of the sample and the consequent chemical analysis through a protocol that includes regular analysis of duplicates and insertion of samples for quality control.
9.5PRECISION EVALUATION
Regarding the Accuracy Assessment, the Competent Person indicates that the iodine and nitrate grades of the duplicate samples in the 400 x 400, 200 x 200, and 100 x 100 meshes have good correlation with the grades of the original samples; However, it is recommended to always maintain permanent control. In this process, to prevent and detect in time any anomaly that could happen.



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9.6ACCURACY EVALUATION
A QA-QC analysis of the campaign is carried out in the Pampa Blanca Sectors for standard/pattern samples, which were carried out and analyzed by the laboratory, the results obtained show that the variation of the analyzes with respect to the standards used by SQM show acceptable margins, with a maximum of ± 0.53% of NaNO3 and 60 ppm of Iodine.
9.7LABORATORY CERTIFICATION
The Nitrate-Iodine Laboratory is ISO 9001:2015 certified by the international certification organism TÜV Rheinland, from the 16 of March 2020, to the 15 of March 2023 (TÜV Rheinland(a), 2019) (TÜV Rheinland(b), 2019). There’s no previous certification available.
9.8QUALIFIED PERSON’S OPINION OF DATA ADEQUACY
The Competent Person indicates that the methodologies used by SQM to estimate geological resources and reserves in Pampa Blanca are adequate.
The 400 x 400 m drilling grid may imply continuity, average grade of mineralization with a moderate confidence level since there is no certainty that all or part of these resources will become mineral reserves after the application of the modifying factors.
The 200 x 200 m drilling grid generate geological information of greater detail being possible to define geological units, continuity, grades and power. Therefore, at this stage of exploration, sectors for geometallurgical tests can be defined. These resources are qualified as Indicated Resources.
To the extent that the exploration grid is sequentially reduced with drilling 100 x 100 m, 100T and 50 x 50 m, the geological information is more robust, solid which allows a characterization of the mineral deposit with a significant level of confidence. These resources are qualified as Measured Resources.
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10MINERAL PROCESSING AND METALLURGICAL TESTING
The operations of the Pampa Blanca Site were suspended in 2010 so it was under temporary closure in accordance with Exempt Resolution No. 1346/2012 and request for extension in accordance with Resolution No. 1304-20 approves Extension of the Temporary Closure Plan of Pampa Blanca.
Since the second half of 2022 the operation of extraction of caliche and loading of piles was resumed; from March 2023 to start with the operation of iodide production and brine feeding to Solar Evaporation Plant to produce nitrate salts.
During 2024, Pampa Blanca processes operated continuously, Mine, Leaching process, Iodide plant and Solar Evaporation ponds.
10.1HISTORICAL DEVELOPMENT OF METALLURGICAL TESTS
In 2009, SQM created a working group that will be responsible for developing tests to continuously improve the estimation of yield and the recovery of valuable elements, such as iodine and nitrate, from heaps and evaporation ponds. At the beginning of February 2010, the first metallurgical test work program was presented at the facilities of the Pilot Plant located in the Iris sector. Its main objective is to provide, through pilot-scale tests, all the necessary data to guide, simulate, strengthen and generate sufficient knowledge to understand the phenomenology behind production processes.
The initial work program was framed around the following topics:
Reviewing constructive aspects of heaps.
Study thermodynamic, kinetic, and hydraulic phenomena of the heap leaching.
Designing a configuration in terms of performance and production level.
Work program activities are divided into specializations and the objectives of each activity and methodology followed are summarized in the following table.

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Table 10-1. Methodologies to address the most important aspects of heaps leaching of Caliche.
Activity 
Objective 
Methodology 
Heap physical aspectsPile geometry and heightOptimum dimensions and the effect of height on performanceMathematical methods and column leaching tests at different heights.
GranulometryImpact of size and determination of maximum optimumLeaching tests at three levels of granulometry.
LoadingImpact of loading shape and optimization of the operation.Column percolability with different size segregation in loading.
Wetting requirementsDetermination of impact on yield due to wetting effect.Column tests, dry and wet ore
Caliche characterizationCharacterization by mining sectorChemical analysis, XRD and treatability tests.
HydraulicsImpregnation rate, irrigation, and irrigation system configurationEstablish optimumsMathematical methods and industrial level tests.
KineticsSpecies solubilitiesEstablish concentrations of interferents in iodine and nitrate leaching.Successive leaching tests
Effect of irrigation configurationEffect of type of lixiviantColumn tests
Sequestering phasesImpact of clays on leachingStirred reactor tests
System configurationPile reworking studyEvaluate impact on yieldColumn tests
Solar evaporation pondsAFN/brine mixture studyReduction of salt harvesting times.Stirred and tray reactor tests
RoutineSample processingPreparation and segregation of test samples---
Treatability testsData on the behavior of caliche available in heaps according to the exploited sector.Column tests
Quality control of irrigation elements and flowmetersReview of irrigation assurance control on a homogeneous basis
This first metallurgical test work plan results in the establishment of appropriate heap dimensions, maximum ROM size and heap irrigation configuration. In addition to giving way to studies of caliche solubilities and their behavior towards leaching. Diagram of chemical, physical, mineralogical, and metallurgical characterization tests applied to all company resources.
SQM, through its Research and Development area, has carried out the following tests at plant and/or pilot scale that have allowed improving the recovery process and product quality:
Iodide solution cleaning tests.
Iodide oxidation tests with Hydrogen and/or Chlorine in the Iodine Plant.
The cleaning test made it possible to establish two stages prior to the oxidation of solution filtration with an adjuvant and with activated carbon. In addition, it is defined that to intensify the cleaning work of this stage, it is necessary to add traces of sulfur dioxide to the iodide solution. Meanwhile, the iodide oxidation tests allowed incorporating the use of hydrogen peroxide and/or chlorine in adequate proportions to dispense with the iodine concentration stage by flotation, obtaining a pulp with a high content of iodine crystals.
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Currently, the metallurgical tests performed are related to the physicochemical properties of the material and the behavior during leaching. The procedures associated with these tests are described below.
10.2METALLURGICAL TESTING
The main objective of the tests developed is to be assessing different minerals' response to leaching. In the pilot plant-laboratory, test data collection for the characterization and recovery database of composites are generated. Tests detailed below have the following specific objectives:
Determine whether analyzed material is sufficiently amenable to concentration production by established separation and recovery methods in plant.
Optimize this process to guarantee a recovery that will be linked intrinsically to mineralogical and chemical characterization, as well as physical and granulometric characterization of mineral to be treated.
Determine deleterious elements, to establish mechanisms for operations to keep them below certain limits that guarantee a certain product quality.
SQM's analytical and pilot test laboratories perform the following chemical, mineralogical and metallurgical tests:
Microscopy and chemical composition
Physical properties: Tail Test, Borra test, Laboratory granulometry, Embedding tests, Permeability.
Leaching test

10.2.1 Sample Preparation
Samples for metallurgical testing are obtained through specific sampling campaigns, the methodologies used correspond to different campaigns to obtain drilling samples, for analysis through a drilling campaign with 100T-200T mesh and diamond drilling.
With the classified material from the test wells, composite samples are prepared to determine the grades of iodine and nitrate, and to determine the physicochemical properties of the material to predict its behavior during leaching.
The samples are segregated according to a mechanical preparation guide, which aims to provide effective guidance for the minimum mass required and characteristic sizes for each test, to optimize the use of available material.
This allows successful metallurgical tests, ensuring the validity of the results and reproducibility. The method of sampling and development of metallurgical tests on samples, for the projection of future mineral resources, consists of a summary of the steps described in Figure 10-1.
Figure 10-1. General stages of the Methodology of Sampling and Development of Metallurgical Tests in Pampa Blanca.
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As for the development of metallurgical tests, characterization, leaching and physical properties, these are developed by teams of specialized professionals with extensive experience in the mining-geometallurgical field. The metallurgical testing work program contemplates that the samples are sent to internal laboratories to carry out the analysis and testing work according to the following detail:
The analysis laboratories located in Antofagasta provide chemical and mineralogical analysis.
Pilot Plant Laboratory, located in Iris- Nueva Victoria, to perform physical response and leaching tests.
Details of the names, locations and responsibilities of each laboratory involved in the development of metallurgical testing are presented in Section 10.2 Analytical and testing laboratories. Reports documenting drilling programs provide detailed descriptions of sampling and sample preparation methodologies, analytical procedures that meet current industry standards. Quality control is implemented at all stages to ensure and verify that the process of harvesting occurs at each stage successfully and is representative. To establish the representativeness of the samples, below is a map of a diamond drilling campaign in Pampa Blanca, Sector 4, to estimate the physical and chemical properties of the caliche of the resource to be exploited (Figure 10-2).

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Figure 10-2 Map of the Diamond Drilling Campaign for Composite Samples Faena Pampa Blanca Sector 4 for Metallurgical Testing.
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10.2.2 Caliche Mineralogical and Chemical Characterization
As part of the work, mineralogical tests are performed on composite samples. To develop its mineralogical characteristics and alterations, a study of the elemental composition is carried out by X-Ray Diffraction (XRD). A particle mineral analysis ("PMA") to determine mineral content of the sample is carried out.
Caliche mineralogical characterization runs for the following components: Nitrate, Chloride Iodate, Sulphate and Silicate.
On the other hand, caliche chemical characterization in iodine (ppm), nitrate (%) and Na2SO4 (%), Ca (%), K (%), Mg (%), KClO4 (%), NaCl (%), Na (%), Na (%), H3BO3 (%), and SO4 were obtained from chemical analyses obtained from an internal laboratory of the company.
The methods of analysis are shown in Table 10-2.
The protocols used for each of the methods are properly documented with respect to materials, equipment, procedures and control measures. Details of the procedure used to calculate iodine and nitrate grades are provided in Section 10.2.3.
Table 10-2. Chemical Analysis Methodologies for Different Species
ParameterUnitMethod
Iodine grade(ppm)Volumetric redox
Nitrate grade(%)UV-Vis
Na2SO4
(%)Gravimetric/ICP
Ca(%)Potentiometric/Direct Aspiration-AA
or ICP Finish
Mg(%)Potentiometric/Direct Aspiration-AA
or ICP Finish
K(%)Direct Aspiration-AA
or ICP Finish
SO4
(%)Gravimetric/ICP
KClO4
(%)Potentiometric
NaCl(%)Volumetric
Na(%)Direct Aspiration-AA/ICP
or ICP Finish
H3BO3
(%)Volumetric
or ICP Finish
In-house analytical laboratories operated by company personnel are responsible for the chemical and mineralogical analysis of samples. These laboratories are in the city of Antofagasta and correspond to the following facilities:
Caliche-Iodine Laboratory
Research and Development Laboratory
Quality Control Laboratory
SEM and XRD Laboratory
Results reported by the company are conclusive on the following points:
The most soluble part of the saline matrix is composed of sulphates, nitrates and chlorides.
There are differences in the ion compositions present in salt matrix (SM).
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Anhydrite, Polyhalita, glauberite and less soluble minerals, have calcium sulphate associations.
From a chemical-salt point of view, this deposit is favorable in terms of the extraction process, as it contains an average of 49% of soluble salts, high contents of calcium (>2.5), good concentrations of chlorides and sulphates (about 11% and 13% respectively).
Being a mostly semi-soft deposit, allows to develop Surface Mining, in almost all the deposit, this geomechanical condition together with a low clastic content and low abrasiveness (proven by calicatas) would allow to estimate a low mining cost when applying this technology.

10.2.3 Caliche Nitrate and Iodine Grade Determination
Composite samples are analyzed using iodine and nitrate grades. The analyzes are carried out by the Caliche and Iodine laboratory located in the city of Antofagasta. Facilities for iodine and nitrate analysis have qualified under ISO-9001:2015 in which TÜV Rheinland provides quality management system certification. The latest recertification process was approved in November 2020 and is valid until March 15, 2023.

10.2.3.1 Iodine determination
The methodology to determine iodine in caliche is the redox volumetry, it is based on titration of an exactly known concentration solution, called standard solution, which is gradually added to another solution of unknown concentration, until chemical reaction between both solutions is complete (equivalence point).
Quality control controls consist of equipment condition checks, sample reagent blanks, titrator concentration checks, repeat analysis for a standard with sample configured to confirm its value.


10.2.3.2 Nitrate determination
Nitrate grade in caliches is determined by UV-Visible Molecular Absorption Spectroscopy. This technique allows to quantify parameters in solution, based on their absorption at a certain wavelength of the UV Visible spectrum (between 100 and 800 nm).
This determination uses a Molecular Absorption Spectrophotometer POE-011-01 or POE-17-01, in which a glass test tube containing a filtered solution obtained by leaching with filtered distilled water is used. Result obtained is expressed in % nitrate.
Quality assurance criteria and result validity are as follows:
Prior equipment verification.
Perform comparative nitrate analysis once a shift, by contrasting readings of the same samples with other UV-VIS equipment and checking readings in Kjeldahl method distillation equipment, for nitrogen determination.
Standard and QC sample input every 10 samples.
Although the certification is specific to iodine and nitrate grade determination, this laboratory is specialized in chemical and mineralogical analysis of mineral resources, with long-standing experience in this field. According to the authors, quality control and analytical procedures used at the Antofagasta Caliches and Iodine laboratory are of high quality.
Figure 10-4. UDK 169 with AutoKjel Auto Sampler - Kjeldahl Automatic Nitrogen Protein Analyzer

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10.2.4 Caliche Physical Properties
To measure, identify and describe a mineral, physical tests of mineral properties are developed to predict how it will react under certain treatment conditions. The tests performed are summarized in Table 10-3. During the site visit it was possible to verify the development of the embedding, sedimentation and compaction tests in the Iris Pilot Plant Laboratory, shown in Figure 10-5.
Table 10-3. Determination of Physical Properties of Caliche Minerals.
TestParameterProcedureObjectiveImpact
Tails testSedimentation and CompactionSedimentation test, measuring the clearance and riprap cake every hour for a period of about 12 hours.Obtain the rate of sedimentation and compaction of fines.Evidence of crown instability and mud generation. Irrigation rate
Borra test% of fine materialThe retained material is measured between the - #35 #+100 and -#100 after a flocculation and decantation process. flocculation and decantation of oreTo obtain the amount of ore flocculation and decantation process% of fine that could delay irrigation.
Irrigation rate.
Canalizations.
Size distribution% of microfineStandard test of granulometry, the percentage under 200 mesh is given.Obtain % microfine% Water retention and yield losses
PermeabilityK (cm/h)Using constant load permeameter and Darcy's lawTo measure the degree of permeability of oreDecrease in extraction kinetics of extraction
EmbeddedalphaWettability measurement procedure of rockTo measure the degree of wettability of the oreVariability in impregnation times

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Figure 10-5. Embedding, Compaction and Sedimentation Tests carried out in the Iris Pilot Plant Laboratory.
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Table 10-4 provides a summary of the results of the physical tests comparing the conditions of caliche in sector 4 Pampa Blanca.

Table 10-4. Comparative Results of Physical tests for caliches of Sector 4 Pampa Blanca.
Sector 4SedimentationCompaction% Fines#200 (%)Alpha
Caliche PB0.035.717.66.22.4
Overburden PB0.0135.539.516.72.5
According to them, it is possible to highlight the following points:
The caliche of Pampa Blanca (PB) presents better behavior than the overburden in all the parameters of the test.
Overburden should be avoided.
The caliche of PB sector 4 is a caliche of medium quality / high treatability, good leaching behavior in Piles.
As the physical properties measured are directly related to the irrigation strategy, the conclusion of the PB caliche should be treated considering a standard impregnation stage of mixed drip and sprinkler irrigation.
Physical characterization modification and improvement.

During 2024, a modification to the physical tests was implemented, in order to automate those currently being performed. For this, the procedure was to carry them out in parallel to those already being performed, in order to continue in 2025 with only the automated tests.

Automated Soil Particle Size Analysis:

It calculates the particle size distribution by Stokes’ law, with a range spanning from 63 μm to 2 μm, instead of just a few measurements at discrete time points. It allows for unattended, automated operation. This results in an overall error rate of 0.5%—lower conventional particle size analysis method.

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Results analysis:
This type of information allows estimating the amount of fine material (-10#) that can cause percolation problems in the leaching heap, being all particle sizes smaller than 50 micrometers, or so called silt (limo) and clay (arcilla), that affect percolation.

Figure 10-6. Silt content in Pampa Blanca
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Figure 10-7. Silt variogram in Pampa Blanca
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At Pampa Blanca the variability is greater, the nugget is smaller in relative terms and the effect of distance is more appreciable.


10.2.5 Agitated Leaching Tests
Leaching tests are performed at the company's internal laboratory facilities located at the Iris Pilot Plant. The following is a brief description of the agitated and successive leaching test procedure.
Leaching in stirred reactors.
Leaching experiments are conducted at atmospheric pressure and temperature in a glass reactor without baffles. A propeller agitator at 400 RPM was used to agitate leach suspension. In short, all the experiments were executed with:
Ambient conditions.
Caliche sample particle size 100% mesh -65# mesh.
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Caliche mass 500 g.
L/S ratio 2:1.
Leaching time 2 h.
Three contact leaching including use of drainage solution.
To start up the leaching experiment, a reactor was initially filled with distilled water and then the solution is gently agitated. After a few minutes, PH and ORP values were set, then caliche concentrate is added to the solution and increased agitation to the final rate.
Once finished, we filtered the product and analyzed this brine solution by checking the extraction of analytes and minerals by contact with the leaching agent, consumption per unit and iodine extraction response.
Successive leaching is complementary to stirred vessel leaching, these are also performed in a stirred vessel with the same parameters explained above, however, it contemplates leaching three caliche samples successively with the resulting drainage solution of each stage. The objective of this test is to enrich this solution of an element of interest such as iodine and nitrates to evaluate heap performance as this solution percolates through the heap. The representative scheme of successive leaching in stirred vessel reactors is shown in:

Figure 10-8. Successive leach test development procedure

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The extraction of each analyte and minerals per contact is analyzed. These results reported by the company are conclusive on the following points:
Higher quantity of soluble salts, lower is the extraction.
Higher proportion of calcium in Salt Matrix results in higher extraction.
Physical and chemical quality for Leaching is determined by a Soluble Salts content of less than 50%.

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Table 10-5. Successive leaching test results, caliches Pampa Blanca Sector 4
SampleIodine (%)Nitrate (%)
PB166%95%
PB267%90%
PB368%99%
PB468%96%
PB561%87%
PB653%93%
PB764%94%
PB860%89%
PB961%86%
PB1061%96%
Average63%92%





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10.2.6 Metallurgical Recovery Estimation
Caliche characterization results are contrasted with metallurgical results to formulate relationships between elemental concentrations and recovery rates of the elements of interest or valuable elements and reagent consumption.
The relationships between reported analyses and recoveries achieved are as follows:

1.It is possible to establish an impact regarding recovery based on the type of salt matrix and the effect of salts in the leaching solution. With higher amounts of soluble salts, extraction is lower while higher calcium in SM results in higher extraction.

2.Caliches with better recovery performance tend to decant faster (speed) and compact better.

3.The higher presence of fines hinders bed percolation, compromising the ability to leach and ultrafine that could delay irrigation or cause areas to avoid being irrigated.

4.The higher hydraulic conductivity or permeability coefficient, better the leachability behavior of the bed.
For metallurgical recovery estimation, the formulated model contains the following elements:

1.Chemical-mineralogical composition.

2.Yield.

3.Physical characteristics: sedimentation velocity, compaction, percentage of fines and ultrafine, uniformity coefficient, and wetting.
The metallurgical analysis is focused on determining the relationships associated with these variables, since the relationships can be applied to the blocks to determine deposit results. From a chemical and yield point of view, a relationship is established between unit consumption (UC, amount of water) or total irrigation salts (salt concentration, g/L) and iodine extraction. The best subset of the regressions was used to determine the optimal linear relationships between these predictors and metallurgical results. Thus, iodine and nitrate recovery equations are represented by the following formulas and Figure 10-9:
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Figure 10-9. Iodine Recovery as a Function of total Salts Content.
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The graph of Figure 10-9 compares iodine yield results for samples from two SQM resources, TEA and Pampa Orcoma (abbreviated as ORC), as a function of total salts. The mineral samples (MS) are differentiated by their percentage soluble salt content, so that sample MS-45 (TEA), for example, corresponds to a mineral sample from the TEA sector characterized by 45% soluble salts. Following this logic, MS-45 (ORC), corresponds to a mineral sample from Pampa Orcoma, which has a soluble salt content of 45%. As can be seen, an output matrix content of 65% implies a lower recovery compared to an ore content of 45%.
In conclusion, the metallurgical tests, as previously stated, have allowed establishing baseline relationships between caliche characteristics and recovery. In the case of iodine, a relationship is established between unit consumption and soluble salt content, while for nitrate, a relationship is established depending on the grades of nitrate, unit consumption and the salt matrix. Relationships that allow estimating the yield at industrial scale.

10.2.7 Irrigation Strategy Selection
In terms of physical properties, the metallurgical analysis allows to determine caliche classification as unstable, very unstable, stable, and very stable, which gives rise to an irrigation strategy in the impregnation stage. As a result, a parameter impact ranking is established in caliche classification, in the order indicated below (from higher to lower impact):
1.Compaction degree (C).
2.Sedimentation velocity (S).
3.Fines and ultrafine percentage (%f; percent passing #200) with wetting degree (α).
4.Uniformity degree (Cu).
The weighting establishes a value to be placed on a scale of selection depending on the type of impregnation for the highest yield (see Figure 10-10):
1.Scale 1.1 to 1.9; pulse ramp 70 days of irrigation with intermediate solution.

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2.Scale 1.9 to 2.6; pulse ramp 60 days of irrigation with intermediate solution.

3.Scale 2.6 to 3.3; pulse ramp 50 days of irrigation with water.

4.Scale 3.3 to 3.9; pulse ramp 40 days of irrigation with water.
Figure 10-10. Parameter Scales and Irrigation Strategy in the Impregnation Stage.
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10.2.8 Industrial Scale Yield Estimation
All the knowledge generated from the metallurgical tests carried out, is translated into the execution of a procedure for the estimation of the industrial scale performance of the pile. Heap yield estimation and irrigation strategy selection procedure is as follows:
1.A review of the actual heap Salt Matrix was compared to results obtained from diamond drill hole samples from the different mining polygons. The correlation factor between the two is obtained, which allows determining, from the tests applied to diamond drill hole samples, how the heap performs in a more precise way.

2.With the salt matrix value, a yield per exploitation polygon is estimated and then, through a percentage contribution of each polygon's material to heap construction, a heap yield is estimated.

3.Based on percentage physical quality results for each polygon, i.e., C m/min, compaction, % fine material, Alpha, #-200, an irrigation strategy is selected for each heap.
For example, for Pile 583, the physical test showed that the pile tends to generate mud in the crown and was unstable. A 60-day wetting was recommended to avoid generating turbidity. The recommendation was to irrigate at design rate.
The real composition for Pile 583, determined by the diamond drilling campaign by polygon is shown in the Table 10-6 in which some differences can be observed.

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Table 10-6 Comparison of the Composition Determined for the 583 Heap Leaching Pile in Operation at Nueva Victoria.
TypeReal vs. Diamond Salts Matrix
Iodine grade
(ppm)
Nitrate grade
(%)
Na2SO4CaMgKKClO4NaClNaH3BO3Saline Soluble
Sample4004.017.92.01.30.50.110.14.30.357.8
Real4244.216.41.91.20.61.410.54.60.358.3
Through the established methodology, composition and physical properties, the resulting 583 pile yield estimate is 54.5%. The estimation scheme is as shown in Figure 10-11.
Figure 10-11. Irrigation Strategy Selection
Participation of Polygon
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The annual industrial throughput values with the values predicted by the model are shown in the Figure 10-12 in which a good degree of correlation is observed.
The annual industrial throughput values with the values predicted by the model are shown in the following figures and in which a good degree of correlation is observed.

Figure 10-12. Nitrate and Iodine Yield Estimation and Industrial Correlation

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The new correlation to project nitrate and iodine yield is made with data from 10 years of industrial operation. This correlation relates the availability of water (CU) to the amount of soluble salts (Caliche*SS*MS) to be dissolved present in the caliche and is directly related to the species of interest (Iodine and Nitrate).

Nueva Victoria has operated in ranges of CU 0.40 m3/t and 0.6 (m3/t). The higher the CU, the lower the CRS (Recirculating charge Salt), therefore the better the performance.

Caliches with high soluble salts (SS), the CRS increases, the increase in CU is more significant.
Caliche with low SS, less steep slope, the CU is not as significant
ST Purge to Ponds: Total salts present in Afa to evaporating solar ponds.
Unit Consumption: Corresponds to fresh water to leachate by mass of treated caliche.

MS: total salt contained in caliche

SS: soluble salts
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10.3QUALIFIED PERSON´S OPINION
Gino Slanzi Guerra, QP responsible for metallurgy and resource treatment, points out the following aspects:
Physical and Chemical Characterization
Mineralogical and chemical characterization results, as well as physical and granulometric characterization of the mineral to be treated, which are obtained from the tests performed, allow to continuously evaluate different processing routes, both in initial conceptual stages of the project and during established processes, in order to ensure that such process is valid and up to date, and/or also to review optimal alternatives to recover valuable elements based on the nature of the resource. Additionally, analytical methodologies determine deleterious elements, in order to establish mechanisms in operations so that these can be kept below the limits to ensure a certain product quality.
Chemical-Metallurgical Tests
Metallurgical test work performed in laboratories and pilot plants are adequate to establish proper processing routes for caliche resources.
Testing program has evidenced adequate scalability of separation and recovery methods established in plant to produce iodine and nitrate salts. In this way, it has been possible to generate a model that can determine, before initiating the operation, to plan the initial irrigation stage to improve iodine and nitrate recovery in leaching.
Samples used to generate metallurgical data are sufficiently representative to support estimates of planning performance and are suitable in terms of estimating recovery from the mineral resources.
Innovation and Development
The company has a research and development team that has demonstrated important advances regarding development of new processes and products in order to maximize returns from exploited resources.
Research is developed by three different units covering topics such as chemical process design, phase chemistry, chemical analysis methodologies and physical properties of finished products. Properly covering raw material characterization, operations traceability and finished product.

11MINERAL RESOURCE ESTIMATE
11.1KEY ASSUMPTIONS, PARAMETERS AND METHODS
This sub-section contains forward-looking information related to a density grade for the Project. The material factors that could cause actual results to differ materially from the conclusions, estimates, designs, forecast or projections in the forward-looking information include any significant differences from one or more of the material factors or assumptions that were set forth in this sub-section including actual in-situ characteristics that are different from the samples collected and tested to date, equipment and operational performance that yield different results from current test work results.
The resource estimation process is different depending on the drill hole spacing grid available in each sector:
Measured Mineral Resources: Sectors with a Block Model, with a drill hole spacing grid of 50 x 50 m, 100 x 100 m and 100T were estimated with a full 3D block model using Ordinary Kriging (OK), which contains variables, such as Iodine, Nitrate, soluble salts, geology, geotechnics, topography, etc. For Pampa Blanca all sectors defined Measured Resources have an available Block Model.
Indicated Mineral Resources: Sectors with a Block Model, with a drill hole spacing grid of 200 x 200 m were estimated with a block model using Inverse of Distance Weighted (IDW) which contains variables, such as Iodine, Nitrate, elements, geology, geotechnics, topography, etc. For Pampa Blanca all sectors defined Indicate Resources have an available Block Model.
Inferred Mineral Resources: Sectors with a drill hole spacing grid greater than 200 x 200 m up to 400 x 400m were estimated in 2D using the Polygon Method. This Inferred Resources do not have block model. The output are polygons which are then transformed to tonnage by multiplying by the area, thickness and density.
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11.1.1 Sample Database
The 2024 Pampa Blanca Model included the estimate of Iodine and Nitrate, and in the case of smaller grids Measured Mineral Resources includes soluble Salts, elements, lithology and hardness parameters.
Table 11-1 and Table 11-2 summarizes the basis statistics of Iodine and Nitrate for Pampa Blanca Sector 4 and Sector 5, sectors that are all reserves.

Table 11-1. Basic sample statistics for Iodine in Pampa Blanca Sector 4 and 5
SectorVariableNumber of SamplesMinimumMaximumMeanStd. Dev.Variance
Pampa Blanca S4Iodine92,419502,595388.9341.2116,421
Pampa Blanca S5Iodine33,024502,000446.2406.9165,648

Table 11-2. Basic sample statistics for Nitrate in Pampa Blanca Sector 4 and 5
SectorVariableNumber of SamplesMinimumMaximumMeanStd. Dev.Variance
Pampa Blanca S4Nitrate92,4191225.574.0816.61
Pampa Blanca S5Nitrate33,0241205.733.9416


11.1.2 Geological Domains and Modeling
For the estimation of each block within a geological unit (UG) only the composite grades, elements and hardness parameters found in that domain are used (Hard contact between UG). The main UG are described as:
Overburden, Cover (UG 1).
Mineralized mantle, Caliche (UG 2).
Underlying (UG 3).



Figure 11-1. Pampa Blanca Sector IV Geological Model

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11.1.3 Assay Compositing
Considering that all the sample have the same length (0.5 m) and the block height is also 0.5 m, SQM did not composite the sample database and used directly in the estimation process.

11.1.4 Evaluation of Outlier Grades, Cut-offs, and Grade Capping
Definition and control of outliers is a common industry practice that is necessary and useful to prevent potential overestimation of volumes and grades. SQM has not established detection limits (upper limit) in the determined grades of Iodine and Nitrates in the analyzed samples. The distribution of grades for both Iodine and Nitrates within the deposit were such that not samples were judged to be extreme, so no sample restrictions were used in the estimation process.

11.1.5 Specific Gravity (SG)
At the Pampa Blanca Site, 193 density measurements were carried out with the Archimedes principle in the different sectors. This method is applicable to any type of samples, whether irregular samples (control) or cylindrical samples (test tube). The associated standards and recommendations correspond to those specified by ASTM. In this case, the following ASTM D-4531 and ASTM D-4543 will be used. The test consists of weighing a previously dried sample, submerging a rock sample or a test tube in melted paraffin and weighing its weight in air and submerged in water. This process will determine the unit weight of the sample, in relation to the properties of the water (density) and the weight differences that the sample presents in 3 environments: dry, dried with paraffin and immersed with paraffin.
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A geophysical study was also carried out using the Well Profiling technique at the Pampa Blanca. This study has provided a detailed view of key physical properties in the characterization of subsurface lithology through the use of Caliper, Natural Gamma and Density probes. In this process, measurements were made in 15 wells, covering a maximum depth of 6 meters, providing valuable data for the evaluation of the strata of interest. The data obtained from the drilling carried out, with sampling at intervals of one centimeter, were processed independently for each well. Finally, a comparison is made between the densities obtained through profiling and those calculated in the laboratory, provided by the client for analysis. This comparison allows the precision of in situ measurements to be evaluated against laboratory results, offering a comprehensive perspective on the consistency and reliability of the data collected.
Table 11-3 shows the sector, the laboratory, the samples and drilling analyzed and the specific gravity. These results justified the historical value used by SQM (2.1 gr/cc).

Table 11-3 Specific Gravity Samples in Pampa Blanca
MiningLaboratoryN° SampleSpecific Gravity gr/cc
Pampa BlancaInternal682.2
External1252.2
Gamma - Gamma152.0
Average2.13

















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Figure 11-2. Pampa Blanca density study sample distribution plan.
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11.1.6 Block Model Mineral Resource Evaluation
As mentioned before, sectors with a drill hole spacing grid greater than 50 x 50 m up to 100 x 100 m were estimated with a full 3D block model using Ordinary Kriging and the sector with a drill hole grid greater than 100 x 100 m and up to 200 x 200 m were estimated using Inverse Distance Weighted also using block model, for interpolation of Iodine, Nitrate, soluble salts, geology, geotechnics, topography, etc. For Pampa Blanca all sectors defined Measured and Indicated Resources have an available Block Model.

11.1.6.1 Block Model Parameters and Domaining
Table 11-4 shows the definition for the block model built in Datamine Studio 3. The block size is 25 x 25 x 0.5 m in all sectors.
Table 11-4. Block Model Dimensions
SectorParametersEastNorthElevation
Pampa blanca S4Origin (m)432,1757,440,5251,366
Range (m)7,6508,600143
Final (m)439,8257,449,1251,509
Block Size25250.5
N° of Blocks306344286
Pampa blanca S5Origin (m)428,1757,441,1251,365
Range (m)3,9502,40056
Final (m)432,1257,443,5251,421
Block Size25250.5
N° of Blocks15896112

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Figure 11-3. Block model location in Pampa Blanca Sector 4 - 5.

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Variography
Experimental variogram where constructed using all the drill hole samples independent of the UG. The variogram is modeled and adjusted, obtaining parameters such as structure range and sill, nugget effect and the main direction of mineralization. Experimental variograms were calculated and modeled for Iodine and used in the estimation of both Iodine and Nitrate.
Table 11-5 describes the variogram models for Iodine used in each zone for the estimation of Iodine and Nitrate.
Table 11-5. Variogram Models for Iodine in Pampa Blanca Sectors 4 and 5
SectorVariableRotationNugget EffectRange 1Sill 1
ZYXZYX
PBIodine00034,0770.5016312344,124
Nitrate0005.590.501541637
The nugget effect is 18.9% of the total sill, this suggests different behavior of Iodine between each zone. The total ranges are around 100 m to a maximum of 150 m. These variogram ranges are in line with the SQM´s definition of Measured Mineral Resources, namely estimates blocks using a drill hole grid greater then 50 x 50 m up to 100 x 100 m. (Block model evaluation).
The QP performed and independent analysis to confirm the variogram models used by SQM, in general, obtains similar nugget effect, total sill and variogram ranges to those used by SQM.

Figure 11-4. Variogram Models for Iodine in Pampa Blanca Sectors 4 and 5.
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Interpolation and Extrapolation Parameters
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The estimation of Iodine and Nitrate grades for Pampa Blanca has been conducted using Ordinary Kriging (KO) in one pass for each UG. SQM used cross-validation to determine the estimation parameters such as search radius, minimum and maximum number of samples used, etc. In the cross-validation approach, the validation is performed on the data by removing each observation and using the remaining to predict the value of remove sample. In the case of stationary processes, it would allow to diagnose whether the variogram model and other search parameter adequately describes the spatial dependence of the data.
The Block model is intercepted with the geological model to flag the geological units used in the estimation process.
The OK plan included the following criteria and restrictions:
No capping used in the estimation process.
Hard contacts have been implemented between all UG.
No octant restrictions have been used for any UG.
No samples per drill hole restrictions have been implemented for any UG.
Table 11-6 summarizes the orientation, radio of searches implemented and the scheme of samples selection for each UG and sector. Search ellipsoid radio were chosen based on the variogram ranges.

11-6. Sample Selection for Sectors 4 and 5.
SectorVariableRotationRange 1Samples
ZYXZYXMinimumMaximum
PBIodine0000.50163.00123.003.020.0
Nitrate0000.50154.00163.003.020.0
After the estimation is done, a vertical reblocking was performed transforming the 3D block model in a 2D grid of points (coordinates X and Y) with the mean grades of all estimated variables. When the 2D grid points are available, operational and mine planning parameters are applied to determine tonnage/grade curves according to iodine grades required. Finally, GIS software (Arcview and Mapinfo) is used to draw the polygons, limiting the estimated Mineral Resources with economic potential.
An example of this methodology is shown in for Pampa Blanca Sector V. The black line defines polygons above the cutoff grade and that comply with several operational conditions (at least 50 x 50 m, not isolated polygons, no infrastructure nearby, etc.).

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Figure 11-5. Plan view of the polygons bordering The Mineral Resources Pampa Blanca Sector 5
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Block Model Validation
A validation of the block model was carried out to assess the performance of the OK and the conformity of input values. The block model validation considers:
Statistical comparison between estimated blocks and samples grades of drill holes.
Global and local comparison between estimated blocks and samples through each direction (East, North and elevation) performing the following test: Anisotropy analysis, Search Neighborhood, Similarity analysis, Seasonality Analysis, Multivariate comparison, cumulative Distribution Function, Trend analysis Near Neighbor (NN).
Visual validation to check if the lock model matches the sample data.










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11.1.6.2 Global Statistics
The QP carried out a statistical validation between sample grades and estimated blocks. Global statistics of mean grades for the samples can be influenced by several factors, such as sample density, grouping and, to a greater extent, the presence of high grades.
Consequently, global statistics of samples grades were calculated using the Nearest-Neighbor (NN) method with search ranges like the one used in the estimation. A summary of this comparison is shown in Table 11-7 and Table 11-8 for Iodine and Nitrate respectively, where the negative values indicate a negative difference between block mean grades in relation to composite mean grades, and vice-versa. In general, differences under 5% are satisfactory, and differences above 10% require attention. The result of the estimate shows that relative differences are found within acceptable limits.
Table 11-7. Global Statistics Comparison for Iodine
Sector# Data - BlockMinimumMaximumMeanStd. Dev
Pampa Blanca S4613,483182,000322182
Pampa Blanca S5116,189501,317446183

Table 11-8. Global Statistics comparison for Nitrate
Sector# Data- BlockMinimumMaximumMeanStd. Dev
Pampa Blanca S4613,4830.320.04.82.3
Pampa Blanca S5116,1891.017.05.71.7

11.1.6.3 Swath Plots
To evaluate how robust block grades are in relation to data, the following tests were performed to validate the robustness of the generated model (Anisotropy analysis, Search Neighborhood, Similarity analysis, Seasonality Analysis, Multivariate comparison, cumulative Distribution Function, Trend analysis Near Neighbor NN). Figure 11-6, provides a summary of plots for each variable. In general, results indicate that estimates reasonably follow trends found in the deposit’s grades at a local and global scale without observing an excessive degree of smoothing.

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Figure 11-6. Swath Plots for Iodine – PB5
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Figure 11-7. Swath Plots for Nitrate – PB5
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Visual Validation
To visually validate the iodine and Nitrate estimation, the QP completed a review of a set of cross-sectional and plan views. The validation shows a suitable representation of samples in blocks. Locally, the blocks match the estimation composites both in cross-section and plant views. In general, there is an adequate match between composite data and block model data for Iodine and Nitrate grades. High grade areas are suitably represented, and high-grade samples exhibit suitable control, which validates the treatment of outliers used.
Figure 11-8 present a series of horizontal plant views with the estimated model and the samples for Nitrate and Iodine in PB5.

Figure 11-8. Visual Validation of Iodine (Up) and Nitrate (Down) Estimation, Plan View – PB5

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Reconciliation
During the period between June 1999 and December 2002, SQM compared the block model estimation with the material 18 heap leach piles in Pampa Blanca.
Comparing the grade determined by SQM in the block model versus Cesmec mass balance head grade of the pile, 16 Piles were considered acceptable for Nitrate (error less than 15%) and 15 piles good for Iodine (error less than 20%), validating in this way the geological model and the estimation through geostatistics techniques.
Table 11-8 shows this comparison for the 18 selected piles in Pampa Blanca.

Table 11-8. Comparison Between Block Model Grade and the Grade Measured from Different Piles, Pampa Blanca

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PileNitrate (%)Iodine (ppm)
Block ModelPileErrorBlock ModelPileError
248.17.311.04644366.4
257.97.63.948844310.2
267.16.67.64774398.7
277.97.46.853843922.6
287.67.34.146740315.9
298.37.018.65295084.1
317.97.72.63683466.4
337.36.95.846641711.8
417.15.431.557042534.1
447.37.30.048743412.2
456.76.70.03933715.9
467.47.22.844339412.4
477.26.85.94184014.2
487.37.7-5.2411456-0.9
497.17.01.4412414-0.5
507.46.612.14153925.9
516.96.015.039535710.6
527.16.92.944035225
Average7.47.06.545541310.2


11.1.7 Polygon Mineral Resources Evaluation
This subsection contains forward-looking information related to the establishment of the economic extraction prospects of Mineral Resources for the Project. Material factors that could cause actual results to differ materially from the conclusions, estimates, designs, forecasts or projections in the forward-looking information include any material difference from one or more of the material factors or assumptions set forth in this subsection, including cut-off profit assumptions, cost forecasts and product price forecasts.
For the sectors with a drill hole spacing grid greater than 200 x 200 m up to 400 x 400 m the resource evaluation was performed using at the polygon Method. Table 11-9 shows the economic and operational parameters used to define economic intervals in each drill hole in Pampa Blanca.

Table 11-9. Economic and Operational Parameters Used to Define Intervals for each Drillhole in Pampa Blanca
ParameterValue
Mantle Thickness≥ 2.0 m
Cover Thickness≤ 3.0 m
Waste/Mineral Ratio1

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11.2.MINERAL RESOURCE ESTIMATE
This sub-section contains forward-looking information related to Mineral Resources estimates for the Project. The material factors that could cause actual results to differ materially from the conclusions, estimates, designs, forecast or projections in the forward-looking information include any significant differences from one or more of the material factors or assumptions that were set forth in this sub-section including geological a grade interpretations and controls and assumptions and forecast associated with establishing the prospect for economic extraction.
Table 11-10 summarizes The Mineral Resources estimate, inclusive of reserves, for nitrate and iodine in Pampa Blanca.
Table 11-10. Mineral Resource Estimate, Exclusive of Mineral Reserves, as December 31, 2024
MiningTotal Inferred ResourceTotal Indicated ReosurceTotal Measured Resource
Tonnage (MMTon)Nitrate Grade (%)Iodine Grade (ppm)Tonnage (MMTon)Nitrate Grade (%)Iodine Grade (ppm)Tonnage (MMTon)Nitrate Grade (%)Iodine Grade (ppm)
Pampa Blanca2185.45135266.3559485.0394
Notes:
(1)Mineral Resources are not Mineral Reserves and do not have demonstrated economic viability. There is no certainty that all or any part of the Mineral Resource will be converted into Mineral Reserves upon the application of modifying factors.
(2)The Mineral Resources are based on the application of modifying factors and due to the fact that the caliche deposits are located on the surface, part of the Measured and Indicated Mineral Resources with environmental permits and that are within the envelope of the valorization of the block greater than 3, have been converted into Mineral Reserves. As a consequence of the above, geological resources are provided excluding mining reserves, or which they are included in this Report of Measured Geological Resources, indicated and inferred in this Summary of the Technical Report.

(3)Comparisons of values may not add due to rounding of numbers and the differences caused by use of averaging methods.
(4)The units “Mt”, “ppm” and “%” refer to million tons, parts per million, and weight percent respectively.
(5)The Resource Mineral involves a cut-off benefit (USD/Ton of ore) greater than 0.1 and caliche thickness ≥ 2.0 m.
(6)As the mineral resources estimation process is reviewed and improved each year, mineral resources could change in terms of geometry, tonnage or grades.
(7)Marco Fazzi and Freddy Ildefonso are the QP responsible for the Mineral Resources.

11.3.MINERAL RESOURCE CLASSIFICATION
This sub-section contains forward-looking information related to Mineral Resources classification for the Project. The material factors that could cause actual results to differ materially from the conclusions, estimates, designs, forecast or projections in the forward-looking information include any significant differences from one or more of the material factors or assumptions that were set forth in this sub-section including geological and grade continuity analysis and assumptions.
The Mineral Resources classification defined by SQM is based on drill hole spacing grid:
Measured Resources were defined using the prospecting grids greater than 50 x 50 m up to 100 x 100 m, which allows to delimit with a significant level of confidence the dimensions, mantle thickness and grades of the mineralized bodies as well as the continuity of the mineralization. Variability and uncertain studies carried out by SQM show a relative estimation error less than 5 % .
Indicated Resources were defined using drill holes grid greater than 100 x 100 m up to 200 x 200 m, which allows to delimit with a reasonable level of confidence the dimensions, mantle thickness, tonnage, and grades of the mineralized bodies. Variability and uncertain studies carried out by SQM show a relative estimation error less than 8%.
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Inferred Mineral Resources were defined using drill holes grid greater than the 200 x 200 m and up to 400 x 400 m. When prospecting is carried out in districts or areas of recognized presence of caliche, or when the drill hole grids is accompanied by some prospecting in a smaller grid, confirming the continuity of mineralization, it is possible to anticipate that such resources have a sustainable base to give them a reasonable level of confidence, and therefore, to define dimensions, mantle thickness, tonnages, and grades of the mineralized bodies. The information obtained is complemented by the surface geology the definition of UGs.
11.4MINERAL RESOURCE UNCERTAINTY DISCUSSION
Mineral Resource estimates may be materially affected by the quality of data, natural geological variability of mineralization and / or metallurgical recovery and the accuracy of the economic assumptions supporting reasonable prospects for economic extraction including metal prices, and mining and processing costs.
Inferred Mineral Resources are too speculative geologically to have economic considerations applied to them to enable them to be categorized as Mineral Reserves.
Mineral Resources may also be affected by the estimation methodology and parameters and assumptions used in the grade estimation process including top-cutting (capping) of data or search and estimation strategies although it is the QP’s opinion that there is a low likelihood of this having a material impact on the Mineral Resource estimate.
11.5QUALIFIED PERSON’S OPINION ON FACTORS THAT ARE LIKELY TO INFLUENCE THE PROSPECT OF ECONOMIC EXTRACTION
With the Reopening of Pampa Blanca added to the operational expertise and information available, it is the opinion of the QP that the relevant technical and economic factors necessary to support the economic extraction of the Mineral Resource have been adequately accounted for in the Mine.
The QP is not aware of any environmental, permitting, legal, title, taxation, socioeconomic, marketing, political or other relevant factors that could materially affect the Mineral Resource Estimate that are not discussed in this Technical Report.

12MINERAL RESERVE ESTIMATE
12.1.ESTIMATION METHODS, PARAMETERS AND METHODS
This sub-section contains forward-looking information related to the key assumptions, parameters and methods for the Mineral Reserve estimates for the Project. The materials factors that could cause actual results to differ materially from the conclusion, estimates, designs, forecast or projection in the forward-looking include any significant differences from one or more of the material factors or assumptions that were set forth in this sub-section including Mineral Resource model tons and grade and mine design parameters.
Mineral Reserves estimates are based on sample grades obtained from drill holes executed with reverse air drilling rigs in 200x200 m, 100x100 m, 100 T m (100 x 50 m) and 50x50 m grid spacing.
Measured Resources are evaluated from 3D block model by numerical interpolation techniques (Ordinary Kriging), where nitrate, iodine, and soluble salt content information available from data obtained in drill hole grids with a spacing equal to or less than 100 x100 m.
The Indicated Resources are evaluated from 3D block model by Inverse Distance Weighted (IDW) interpolation technique and defined by drill hole spacing of 200x200 m.
Mineral Reserves considers SQM’s criteria for the mining plan which correspond to the following:
Caliche Thickness ≥ 2.0 m
Overload thickness ≤ 3.0 m
Waste / Mineral Ratio ≤ 1.0

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Cut-off benefit ≥ 3 USD/t
The average production cost corresponds to 32.1 USD/kg and the sales price for Iodine derivatives is 99 USD/kg. For nitrate concentrate brine1, the average production unit cost is 99 USD/ton (mining, leaching, neutralization, and pond treatment) and the unit internal price is 323 USD/ton for nitrates salts for fertilizer
The mining sectors consider in the mining plans (Figure 12-1) are delimited in base of the environmental licenses obtained by SQM and a series of additional factors (layout of main accesses, heap and ponds locations, distance to treatment plants, etc.). Mining is executed in blocks of 25x25 m and the volumes of caliche to be extracted are established considering an average density value applied to 2.1 t/m³ for the deposit.
Using these criteria SQM estimated volumes (caliche) to be considered as Proven Reserves based on the 3D block models built, to define Measured Mineral Resources, and applying the criteria defined above to determine the mining plan.
The Indicated Resources estimated by Inverse Distance Weighted method using the Nitrate and Iodine grades and other relevant data obtained from medium density drill hole prospecting grids (200 x 200 m) are stated as Probable Reserves using the same criteria for mineral reserves describes above, caliche and overload thickness, waste/mineral rates ans cut-off benefit ( ≥ 3 USD/t).

Figure 12-1. Map of Reserves Sectors in Pampa Blanca
image_99.jpg
1
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12.2CUT-OFF GRADE

SQM has historically used an iodine cut-off grade of 300 ppm, for this year it considers an Cut-off Benefit (BC), to maximize the economic value of each block.

This method generates an optimal economic envelope for each pampa for a Cut-off benefit (USD/Ton of mineral) greater than 0.1. In each pampa, the following must be considered:

• The accumulated benefit per ton of mineral in the column must be greater than or equal to the cut-off benefit.

• The last block in the column where the previous condition is met must have a value per ton greater than or equal to the cutoff benefit; otherwise, a vertical search is performed upwards.

12.3CLASSIFICATION AND CRITERIA
This sub-section contains forward-looking information related to the Mineral Reserve classification for the Project. The material factors that could cause actual results to differ materially from the conclusions, estimate, designs, forecast or projections in the forward-looking information include any significant differences from one or more of the material factors or assumptions that were set forth in this sub-section including Mineral Resources model tones, grade, and classification.
The geological features of the mineral deposits (sub-horizontal, superficial and limited thickness) allow to consider all the Mineral Reserves, because, regardless, the method of mining extraction used by SQM (drill & blast, Surface mining), the entire volume/mass of Proven and Probable Reserves can be extracted.
Any mining block (25x25m) that can´t be extracted due to temporary infrastructure limitations (pond, pipes, roads, etc.), are still counted as Mineral Reserves since they may be mined once the temporary limitations are removed.
Proved Reserves have been determined based on Measured Resources, are classified as describe in Section 11.3 with modifying factors, as described in Section 12.1.
Probable Reserves has been determined from Indicated Resources, which are classified as described in Section 11.3. Additional criteria as described in Section 12.1 and Section 12.2.
12.4MINERAL RESERVES

This sub-section contains forward-looking information related to the Mineral Reserve estimates for the Project. The material factors that could cause actual results to differ materially from the conclusions, estimate, designs, forecast or projections in the forward-looking information include any significant differences from one or more of the material factors or assumptions that were set forth in this sub-section including Mineral Resources model tone and grade, modifying factors including mining and recovery factors, production rate and schedule, mining equipment productivity, commodity market and prices and projected operating and capital costs.
Pampa Blanca mine is divided into three sectors: Pampa Blanca, Ampliación Pampa Blanca, and Blanco Encalada.
The Pampa Blanca sector is further subdivided into exploitation sub-sectors (see Figure 12-1).
The Pampa Blanca Sector (located at the Center of Sector) contains the following sub-sectors:
Pampa Blanca Sectors 3 – 4 and 5.
SQM extracts “caliches” from these sectors within areas having environmental license currently approved by the Chilean authorities.
SQM exploits caliche at a rate of up to 5,000 Ktpy for Pampa Blanca plant site (Exempt Resolution N°0515/2012).
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SQM's Mining Plan for 2025-2040 (Pampa Blanca-SQM Industrial Plan) sets a total extraction of 85.3 Mt of caliche with production ranging between 1.3 Ktpy and 1.8 Ktpy. Iodine average grade is 392 ppm and Nitrate average grade is 5.4% for the life-of-mine (LOM).
The criteria for estimating Mineral Reserves are as described below:
1.Measured Mineral Resources defined by 3D Model block and ordinary Kriging using data from high resolution drill hole spacing campaigns (100 x 100 m, 100T m or 50 x 50 m) are used to establish Proven Mineral Reserves.
2.Indicated Mineral Resources defined by 3D Model Block an Inverse Distance Weighted using data from medium resolution drill hole spacing campaigns (200 x 200 m) are used to establish Probable Mineral Reserves.
3.All the prospected sectors at Nueva Victoria have an environmental license to operate, considering the mining method used by SQM (drill-and-blast and SM) and the treatment by heap leach structures to obtain enriched brines of iodine and nitrates.
The modifying factors are considered herein. All permits are current and although there are no formal agreements, the operations have longstanding relationships with the communities, some of which are company towns. Mining, processing, downstream costs, mining loss, dilution, and recoveries are accounted for in the operational cut-off grade. As the project has been in operation since 1997, the risks associated with operating costs and recoveries are considered minimal.

Based on the described rules for resources to reserves conversion and qualification, the Proven Mineral Reserves and Probable Mineral Reserves of Pampa Blanca has been estimated as shown in Table 12-2 summarizes the estimated Mineral Reserves in the different sectors investigated by SQM in the Pampa Blanca mine.

Table 12-2. Mineral Reserves at the Pampa Blanca Mine (Effective 31 December 2024)

Proven ReservesProbable ReservesTotal Reserves
Tonnage (Mt)8585
Iodine Grade (ppm)392392
Nitrate Grade (%)5.45.4
Iodine (kt)33.533.5
Nitrate (kt)4,6134,613

Notes:
a) The Mineral Reserves are based on a Cut-off Benefit (BC) greater than 3 USD/t, a caliche thickness ≥ 2.0 m. and a restriction of sectors with slopes not greater than 8%.
b) Proven Mineral Reserves are based on Measured Mineral Resources at the criteria described in (a) above.
c) Mineral Reserves are declared as in-situ ore (caliche).
d) The units “Mt”, “kt”, “ppm” and % refer to million tons, kilotons, parts per million, and weight percent respectively.
e) Mineral Reserves are based on a nitrates salts for fertilizer price of 323 USD/ton and an Iodine price of 42.0 USD/Kg. Mineral Reserves are also based on economic viability as demonstrated in an after-tax discounted cashflow (see Section 19).
f) Marco Fazzi is the QP responsible for the Mineral Reserves.
g) The QP is not aware of any environmental, permitting, legal, title, taxation, socioeconomic, marketing, political or other relevant factors that could materially affect the Mineral Reserve estimate that are not discussed in this TRS.
h) Comparisons of values may not total due to rounding of numbers and the differences caused by use of averaging methods.
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The final estimates of Mineral Reserves by sector are summarized in the Table 12-3. The procedure used to check the estimates as follows:
1.Verified tonnage and average grades (iodine and nitrate) as Mineral Reserves by sectors with the measured and indicated resources previously analyzed.
1.Checked that the sectors with estimated Mineral Reserves by SQM are in areas with environmental licenses approved by the Chilean authorities while also considering application of modifying factors.
1.Confirmed that each sector with Mineral Reserves is considered in the Long Term mine plan (2025-2040) and the total volume of mineral ore (caliche) is economically mineable.
1.Considered the judgment of the Qualified Person in respect of the technical and economic factors likely to influence the prospect of economic extraction.

Table 12-3. Reserves at the Pampa Blanca Mine by Sector (Effective 31 December 2024)

SectorProvedProbableTotal Reserves
Tonnage (Mt)Nitrate (%)Iodine (ppm)Tonnage (Mt)Nitrate (%)Iodine (ppm)Tonnage (Mt)Nitrate (%)Iodine (ppm)
Pampa Blanca-5 (Cp)145.5533145.5533
Pampa Blanca-4715.4364715.4364
Ampliacion PB Sin RCA-
Total855.4392855.4392

12.5QUALIFIED PERSON’S OPINION
The estimate of mineral reserves is based on Measured and Indicated Mineral Resources. This information has been provided in reference to Pampa Blanca. The Competent Person has audited the mineral resource estimate and modifying factors to convert the measured and indicated resources into proven and probable reserves.
The Competent Person has also reconciled mineral reserves with production and indicates that such reserves are appropriate for use in mine planning.

13. MINING METHODS
SQM provided with production forecasts for the period from 2025 to 2040 (Mining Plan MP). This Mining Plan was checked that the planned exploitation sectors had environmental licenses approved by the Chilean authorities (Prior to Environmental Law); the total tonnage and average Iodine and Nitrate grades were consistent with estimated Mineral Reserves; the total volume of mineral ore (caliche) is economically mineable and the production of prilled Iodine and Brine Nitrate Concentrate (Brine Nitrate) set by SQM is attainable, considering the dilution and mass losses for mining and recovery factors for leaching and processing.
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Mining at the Pampa Blanca mine comprises soil and overload removal, mineral extraction from the surface, loading and transport of the mineral (caliche) to make heap leach pads to obtain iodine and nitrate-enriched solutions (brine leach solution).
Mineralization can be described as stratified, sub-horizontal, superficial (≤ 7.5 m), and limited thickness (3.0 m average). The extraction process of the mineral is constrained by the tabular and superficial bedding disposition of the geological formations that contain the mineral resource (caliches). This mining process has been approved by local mining authorities in Chile (SERNAGEOMIN). Generally, extraction consists of a few meters’ thick excavation (one continuous bench of up to 6.0 m in height (overburden + caliche)) where the mineral is extracted using traditional methods - drilling and blasting. Extracted ore is loaded by front loaders and/or shovels and transported by rigid hopper mining trucks to heap leach structures.
The concentration process starts with leaching in situ by means of heap leach pads irrigated by drip/spray to obtain an iodine and nitrate enriched solution that is sent to treatment plants to obtain the final products. The mining and extraction process is summarized in Table 13-1.
Table 13-1. Summary of Pampa Blanca-SQM caliche mine characteristics
Mining SistemOpencast with a single and continuous bench with a height of up to 6 m
DrillingAtlas Copco Model F9 and D7
Blast Mining (Explosive)ANFO, detonating cord, 150 gr APD booster and non-electric detonators. Power factor 0,365 kg/tonne
Loading and Transportation
Front loaders (12 to 14 m3), 100 to 150 t trucks (60 m3 to 94 m3 capacity)
Top Soil Stripping (overburden removal)
0.15 m3 of soils and overburden/tonne of caliche
Caliche Production15.000 tonnes per day (tpd)
Dilution Factor± 10 ppm Iodine (<2.5%)
Recovery Factor51.7% of Iodine and 38% of Nitrate (2023-2029 period)
Heap Leaching Water Consumption
0.32 to 0.44 m3/tonne leached caliche (2023-2029 period)
Sterile(a)/Ore Mass Ratio
1 t: 2.36t

(a)This material is used by SQM to build the base of the heap pads. The final volume of waste material is negligible.
13.1.GEOTECHNICAL AND HYDROLOGICAL MODELS, AND OTHER PARAMETERS RELEVANT TO MINE DESIGNS AND PLANS
This sub-section contains forward-looking information related to mine design for the Project. The material factors that could cause actual results to differ materially from the conclusions, estimates, designs, forecasts, or projections in the forward-looking information include any significant differences from one or more of the material factors or assumptions that were set forth in this sub-section.
Mining at Pampa Blanca is relatively simple, as it is only necessary to remove a surface layer of sterile material (soil + overburden) up to 2.0 m thick (sandstone, breccia, and anhydrite crusts), which is removed. Subsequently the ore (caliche) is extracted, which has a thickness of 1.50 to 6.0 m (average of 3.0 m). Caliche's geotechnical characteristics (Polymictic Sedimentary Breccia) allow a vertical mining bench face, allowing increased efficiency in the exploitation of the mining resources.
The mining conditions do not require physical stability analysis of the mining working face; therefore, no specific geotechnical field investigations and designs are required. One single final bench of about 4.70 m average height (1.0 m of soil + overburden and 3.2 m of caliche) is typical of the operations (Figure 13-1).

Figure 13-1. Stratigraphic column and schematic profile in Pampa Blanca mine.
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Due to its practically non-existent surface runoff and surface infiltration (area with very low rainfall) and its shallow mining depth, the water table is not reached during excavation. Therefore, no surface water management and/or mine drainage plans are required to control groundwater and avoid problems arising from the existence of pore pressures.
Therefore, this mining operation does not require detailed geotechnical, hydrological and hydrogeological models for its operation and/or mining designs and mining plans.
The hardness is established during geological surveys and exploration and relates to the following qualitative technical criteria as judged by the geologist in the field from boreholes:
Caliche drilled borehole section that exhibits collapse and/or roughness in diameter is rated as Soft (Hardness 1) or Semi-Soft (Hardness 2).
Borehole section drilled in caliche that exhibits a consistent and smooth borehole diameter is rated as Hard (Hardness 3).
This parameter is included in the block model and is used in decision-making on mining and heap leach shaping.
Extracted mineral is stockpiled in heaps located in same general area of exploitation. Heap leach pads are constructed in previously mined-out areas. The pads are irrigated to leach the target components (iodine and nitrates) by aqueous dissolution (pregnant brine solution).
SQM has analyzed heap leach stability2 to verify the physical long-term stability of these mining structures under adverse conditions (maximum credible earthquake). Geomechanical conditions analyzed for heap leaching facilities that are already closed have been considered, which have the following characteristics:
Wet density of 20.4 kilonewtons per cubic meter (kN/m³).
Internal friction angle of 32º.
Cohesion of 2.8 kPa.
A graded compacted material is used to support the liner on which the piles rest. The specification is based on experience and is generally defined by a wet density of 18.5 kN/m³, an angle of friction (𝜙) of 38° and no cohesion. Between the soil base and heap material there is an HDPE sheet that waterproofs the heap leach pad foundation. The interface between geomembrane HDPE and the drainage layer material is modelled as a 10 cm thick layer of material and a friction angle 𝜙 = 25° is adopted, which represents generated friction between the soil and the geomembrane.
2 TECHNICAL REPORT ‘’ANÁLISIS DE ESTABILIDAD DE TALUDES PILAS 300 Y 350’’. Document SQM N° 14220M-6745-800-IN-001. PROCURE Servicios de Ingeniería (21146-800-IN-001), mayo 2021.
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Maximum acceleration value for the maximum credible earthquake is set at 0.86 G (G = 9.8 m/s2) and for the design earthquake it is set at 0.35 G.
The horizontal seismic coefficient (Kh) was set through expressions commonly used in Chile and the vertical seismic coefficient (Kv) was set according to NCh 2369 Of. 2003, as 2/3 of the horizontal coefficient. Therefore, in the stability analysis of heaps, a Kh value of 0.21 and Kv of 0.14 was used for the maximum credible earthquake; and a Kh of 0.11 and Kv of 0.07 were used for the design earthquake.
The stability analysis was executed using the static dowel equilibrium methodology (Morgenstern-Price Limit Equilibrium method) and GeoStudio’s Slope software, with results that comply with the minimum Factor of Safety criteria.
Based on the analysis developed in this document, it is possible to draw the following conclusions (Table 13-2 and Figure 13-2):
The slopes of the heaps analyzed in their current condition are stable against sliding.
None of the heaps will require slope profiling treatment after closure.

Table 13-2. Summary results of slope stability analysis of closed heap leaching.
Slope
Static case (FS adm = 1.4)
Pseudo-static design earthquake (FS adm = 1.2)
Pseudo-static maximum credible earthquake (FS adm = 1.0)
3001.931.421.09
3501.911.421.10
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Figure 13-2. Geotechnical analysis results: Heap n#300, Hypothesis maximum credible earthquake

image_108.jpg

13.2PRODUCTION RATES, EXPECTED MINE LIFE, MINING UNIT DIMENSIONS, AND MINING DILUTION AND RECOVERY FACTORS
The MP considers a total caliche extraction of 42 Mt, with a production growing from 5.0 Mtpy to 12 Mtpy, as shown in Table 13-3. For the MP total caliche to be extracted is projected to have iodine grades ranging between 450 to 470 ppm and nitrate grades between 5.7% and 7.0%.
With an average Iodine grade of 392ppm (0.0392%), gross iodine prill production is estimated to be at 4.2 tpd (1,540 tpy of iodine). Likewise, for a Nitrate average grade of 5.4%, average Nitrate salts for fertilizer production is estimated to be at 362 tpd (95.9 ktpy of nitrate salts for fertilizer).
The mining area extends over an area of 40 km x 50 km. The mining sequence is defined based on the productive thickness data established for caliche from geological investigations, approved mining licenses exist, distances to treatment plants and ensuring that mineral is not lost under areas where infrastructure is planned to be installed (heap bases, pipelines, roads, channels, trunk lines, etc.). Areas with future planned infrastructure are targeted for mining prior to establishing these elements or mined after the infrastructure is demobilized.
Mineral Reserves considers SQM's criteria for the mining plan which includes the following:
Caliche Thickness ≥ 2.0 m.
Slope ≤ 8.0%.
Waste / Mineral Ratio ≤ 1.0.
Cut-off Benefit ≥ 3.0 USD/t
In addition to the above-mentioned operational parameters, the following geological parameters are also considered for determining the mining areas:
Lithologies.
Hardness parameters.
Total salts (caliche salt matrix) which impact caliche leaching.
Total salts elements (majority ions) which impact caliche leaching.
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GPS control over the mining area floor is executed during mining to minimize dilution of the target iodine and nitrate grades.
Table 13-3. Mining Plan planned for 2025-2040.
MATERIAL MOVEMENTUNITS2025202620272028202920302031-2040TOTAL
Pampa Blanca Sector Ore TonnageMt5.55.55.55.55.55.552.385.3
Iodine (I2) in situppm450437422416409399374392
Average grade Nitrate Salts (NaNO3)%7.0%7.0%7.0%6.0%6.0%6.0%5.0%5.4%
TOTAL ORE MINED (CALICHE)Mt5.55.55.55.55.55.552.385.3
Iodine (I2) in situkt2.52.42.32.32.22.219.533.5
Yield process to produce prilled Iodine%72.0%72.0%72.0%71.0%70.0%70.0%67.0%69.0%
Prilled Iodine producedkt1.81.71.71.61.61.513.223.1
Nitrate Salts in situkt3913743583473303192,4954,613
Yield process to produce Nitrates Salts%35.0%35.0%34.0%34.0%33.0%33.0%33.0%33.3%
Nitrate Salts for Fertilizerskt1371291221171101068141,535

Grade dilution from mining is estimated to be less than 2.5% (± 10 ppm iodine) and less than 2.3% for nitrate (± 0.12% nitrate). During the caliche mining process, as the mineralized thicknesses are low (≤ 5.0 m), there is a double effect on the mineralized mantle floor resulting from the blasting process: with the inclusion of underlying material as well as over-excavation. These tend to compensate, with dilution or loss of grade is minor or negligible (± 10 ppm for Iodine).
The excavation depth is controlled by GPS on the loading equipment. SQM considers a planned mining recovery of 95%, (average value for MP 2025-2040).
The processes of extraction, loading and transport of the mineral (caliche) include:
1.Surface layer and overburden removal (between 0.5 to 2.5 m thick) that is deposited in nearby mined out or barren sectors. This material is used to build the base of the heap leaching structures.
1.Caliche extraction, to a maximum depth of 6 meters, using explosives (drill & blast).
Blasting is performed to achieve a high degree of fluffing, good fragmentation, good floor control, mineral sizes suitable for the type of loading equipment and not requiring further handling (20% of fragments below 5.0-6.0 cm, 80% of fragments feed to heap leach below 37.0 cm and maximum diameter of 100 cm).
The SM is not applicable in Pampa Blanca due to the excess of clasts and megaclasts that affect the consumption of cutting tips of the equipment.
The 2025 Mining Plan targets an annual production of 5.5 Mt of fresh caliche (7.0% NaNO3, 450 ppm Iodine and 50.9% soluble salts) of which 5.5 Mt will be extracted by traditional mining and 0 Mt by surface mining.
1.Caliche loading, using front-end loaders and/or shovels.
1.Transport of the mineral to heap leach pads, using mining trucks (rigid hopper, 100 t to 150 t).
Heap leach pads (Figure 13-3) are built to accumulate a total of 0.5 a 1.0 Mt, with heights between 7 to 15 m and crown area of 40,000 a 65,000 m2.
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Figure 13-3. Pad construction and morphology in Pampa Blanca mine (caliches).
image_109.jpg
image_110.jpg
Physical stability analysis performed by SQM reports that these heaps are stable in the long term (closed heaps) and no slope modification is required for closure.
Pampa Blanca mine operates with "Run of Mine" (ROM) material, which is material directly from the mine, coming from a traditional extraction process (drilling and blasting), loading and transport, where it is possible to find particles ranging in size from a few millimeters to 1 meter in diameter.
There are several stages in the heap construction process:
Site preparation (soil removal by tractor) and construction of the heap base and perimeter parapets to facilitate collection of the enriched solutions.
The base of the heaps has an area of 60,000 to 84,000 m² and a maximum cross slope of 2.5% (to facilitate the drainage of solutions enriched in iodine and nitrate salts).
Heap base construction material (0.40 m thick) comes from the sterile material and is roller-compacted to 95% of Normal Proctor (moisture and/or density is not tested on site).
An HDPE waterproof geomembrane is laid on top of this base layer.
To protect the geomembrane, a 0.5 m thick layer of barren material is placed on top (to avoid damage to the membrane by ROM / SM fragments stored in the heap).
Heap loading by high-tonnage trucks (100 to 150 tons). The leach pads are built in two lifts each 3.25 m high, on average. The average high of a heap pad is 6.5 m.
Impregnation, which consists of an initial wetting of the heap with industrial water, in alternating cycles of irrigation and rest, for a period of 60 days. During this stage the pile begins its initial solution drainage (Brine).
Continuous irrigation until leaching cycle is completed, taking into account the following stages:
Irrigation SI: stage where drained solutions are irrigated by the oldest half of heaps in the system. It lasts up to 280 days.
Mixing: irrigation stage consisting of a mixture of recirculated BF and water. Drainage from these heaps is considered as SI and are used to irrigate other heaps. This stage lasts about 20 days.
Washing: last stage of a heap's life, with a final irrigation of water, for approximately 60 days.
In total, there is a cycle of approximately 400 to 500 days for each heap, during which time the heap drops in height by 15-20%.
The irrigation system used is a mixed system, that is, drippers and sprinklers are used. In the case of drippers, an alternative is to cover heaps with a plastic sheet or blanket to reduce evaporation losses and improve the efficiency of the irrigation system.
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Leaching solutions are collected by gravity via channels, which will lead the liquids to a sump where they will be recirculated by means of a portable pump and pipes to the Brine reception and accumulation ponds.
Once the heaps are out of operation, tailings can either be used for base construction of other heaps or remain on site (exhausted heaps).
In the Long term (MP) for 2025-2040 period, the unit water consumptions range from 0.45 to 0.47 m³/ton of caliche leached with an average of 0.46 m³/ton.
Leaching process yields are set at 69.0% for prill iodine and 33.3% for nitrate in ROM heap leaching (drill and blast material), for the Long Term from 2025 to 2040 period.
Heap leaching process performance constraints include the amount of water available, slope shaping3 (slopes cannot be irrigated), re-impregnation and resource/reserve modelling errors, this last factor being the one that most influences annual target production deviations from the one finally achieved. Such deviations are typically as high as -5% for iodine and -7% for nitrate.
From Brine Pond, the enriched solutions are sent to the iodide plants via HPDE pipes.
13.3REQUIREMENTS FOR STRIPPING, UNDERGROUND DEVELOPMENT, AND BACKFILLING
Initial ground preparation work requires an excavation of a surface layer of soil-type material (50 cm average thickness) and overload or waste material above the mineral (caliche) that reaches average thicknesses of between 50 cm to 100 cm.
This is done by bulldozer-type tracked tractors and wheeldozer-type wheeled tractors. This waste material is deposited in nearby sectors already mined or without mineral.
SQM has 4 bulldozer-type tractors of 50 to 70 tons and 2 wheeldozers-type tractors of 25 to 35 tons for these tasks.
Caliche mining is executed through use of explosives to a maximum depth of 6 m (3.0 m average and 1.5 m minimum mineable thickness), with an annual caliche production rate at Nueva Victoria of 5.0 Mtpy.
Caliche extraction by drilling and blasting is executed by means of rectangular blasting patterns, which are drilled considering an average caliche thickness of 3.0 m.
Table 13-4. Blasting pattern in Pampa Blanca mine
Diameter (inches)
Burden (m)
Spacing (m)
Subgrade (m)
3.52.8 to 3.22.2 to 2.80.5 to 0.8
4.02.8 to 3.42.8 to 3.40.7 to 1.2
4.53.4 to 3.83.4 to 3.81.0 to 1.5
Usually, drilling grid used in Pampa Blanca is 2.8mx3.0m and 3.00x3.2m, for a drilling diameter of 4". Atlas Copco rigs are used in drilling - F9 and D7 equipment (Percussion drilling with DTH hammer).
The explosive used is ANFO, which is composed of 94% ammonium nitrate and 6% petroleum, which has a density of 0.82-0.84 g/cc, with a detonation velocity between 3,800 to 4,100 m/s. The charge is 24.3 kg per drill hole.
A backfill (stemming) of 0.80 m is provided with sterile material. For detonation, 150 gr APD boosters and non-electric detonators are used as detonators, which start with a detonating cord. The over-excavation (subgrade) is variable from 0.50 to 1.50 m. Blasting will be executed considering a rock density of 2.1 t/m³ of intact rock, with an explosives load factor of 365 gr/t (load factor of 0.767 kg/m³ of blasted caliche), for an extraction of 15,000 tpd of caliche.

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Figure 13-4. Picture of a typical blast in Pampa Blanca mine (caliches)
image_112.jpg
The unit cost of mine production at Nueva Victoria based on traditional mining is set at 3.34 USD/ton.
13.4REQUIRED MINING EQUIPMENT FLEET AND PERSONNEL
This sub-section contains forward-looking information related to equipment selection for the Project. The material factors that could cause actual results to differ materially from the conclusions, estimates, designs, forecasts or projections in the forward-looking information include any significant differences from one or more of the material factors or assumptions that were set forth in this sub-section including labor and equipment availability and productivity.
SQM has sufficient equipment at the Pampa Blanca mine to produce enough caliche as required, to mine and build heap leach pads, and to obtain enriched liquors that are sent to treatment plants to obtain Iodine and Nitrate end-products.
The equipment available to achieve Pampa Blanca current production Mining Plan (2025-2040) of caliche is summarized in Table 13-5. The current equipment capacity has been evaluated by the QP and will meet the future production requirements.










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Table 13-5 Equipment fleet and Pampa Blanca mine
EquipmentQuantityType or sizeReplacement (h)
Front loader312,5 y 15 m330
Shovels113 a 15 m330
150 a 200 ton
Trucks7100 - 150 ton-c30
Bulldozer450 a 70 ton25
Wheeldozer235 ton25
Drill4Top hammer de 3,5” a 4,5” (diameter)20
Grader216 - 24 feets20
Roller110-15 ton20
Excavator2Bucket capacity 1 -1,5 m320
The staff at Pampa Blanca mining operation consists of 148 professionals dedicated to mining and heap leach operation.
Also, a total of 37 professionals are employed for heap leaching and ponds maintenance.
The Pampa Blanca mine operation includes some general service facilities for site personnel: offices, bathrooms, truck maintenance and washing shed, change rooms, canteens (fixed or mobile), warehouses, drinking water plant (reverse osmosis) and/or drinking water storage tank, sewage treatment plant and transformers.

13.5PRODUCTION AND FINAL MINE OUTLINE

SQM works with an initial topography of the land where, by continuous topography and control of the mining operations, the soil and overload are removed (total thickness of 1.50 m on average at Pampa Blanca) and caliche is extracted (average thickness of 3.0 m).

Given that the excavations are small (4.70 m on average) in relation to the surface area involved (655 Ha/year), it is not possible to correctly visualize a topographic map showing the final situation of the mine.

Figure 13-4 depicts the final mine outline for the 2025 to 2040 period (Long Term Plan).

Figure 13-5. Pampa Blanca Mining Plan 2025-2040
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plan_pblancax2024xi2xesc3.jpg
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Caliche production data for the 2025-2040 LoM involves a total production of 85.3 Mt, with average grades of 392 ppm of Iodine and 5.4% of Nitrates.
The total of water consumption expected is 40.1 Mm³(Mining Plan 2025-2040).

Based on production factors set in mining and leaching processes, a total production of 23.1 kt of Iodine prill and 1,535 kt of Nitrate salts is expected for this period (2025-2040), which means to produce fresh brine solution (6,700 m³/d) with average contents of 4.0 tpd of Iodine (0.60 g/L) and 362 tpd of Nitrate salts (141 g/l) that would be sent to the processing plants. Note that dilution factors considered herein are in addition to the indicated resource to probable reserve factors described above.
Table 13-6. Mine and PAD leaching production for Pampa Blanca Mine – period 2025-2040
LoM 2025-2040Caliches%/RatiosIodineNitrates
Production (Mt)85.3
Average grades (Iodine ppm / Nitrate %)3925.4%
Mineral in situ (kt) RESERVES33.54,613
Traditional mining (kt)85.3100%
Mining yield (%)95%
Grade Dilution Factor (%)2.25%2.50%
Grade dilution (ppm/%)±8.82±0.14%
Mining process efficiency (%)92%92%
Mineral charged in heap leach (kt)33.54,613
Heap Leach ROM recovery from traditional mining (%)74%55%
Heap ROM production from traditional mining heaps (kt)24.792537.15
TOTAL Heap Leach production (kt)24.792537.15
Heap Leaching recovery coefficient (%)74%55%
Recovery Average Coefficient for Finished Product (%)69.0%33.3%
Total Industrial Plant Processing Pampa Blanca (kt)23.11,535

14. PROCESSING AND RECOVERY METHODS

Pampa Blanca is one of SQM's production center located in Sierra Gorda, province of Antofagasta, approximately 100 km northeast of the city of Antofagasta and 25 km northeast of Baquedano. The property was an operations recess stage by Exempt Resolution N°1346/2012 which authorizes the extension of the Pampa Blanca Temporary Closure. The site contemplated caliche extraction processes (mine), heap leaching, and processing plants to obtain iodine as the main product and nitrate (nitrate-rich salts) as a byproduct.

In October 2022, Pampa Blanca was reopened with caliche extraction, pile construction, construction of iodide and alkalinization plant, and reconditioning of evaporation solar ponds. The operation of the iodide plant and pump brines to evaporation ponds started in March 2023, operating continuously the rest of the year.
Pampa Blanca operations currently have the following facilities

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1.Caliche mine and mine leaching operation centers.
2. Electric power generating plant
2. Industrial water Supply
3. Iodine Plant
4. Neutralization Plant
5. Evaporation Ponds
6. Auxiliary Facilities

Show a general plan of the location of the Iodide and Solar Evaporation Plant plants is shown.
Figure 14-1. Location of Pampa Blanca's production plant and facilities.
image_114.jpg
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14.1.PROCESS DESCRIPTION

The SQM operation in Pampa Blanca is focused on the production of iodide and sodium nitrate salts. First stage of the process is the extraction of caliche from different mining reserves, this extraction involves several activities: Preparation of heap base, Overload Removal, Drilling, Blasting Loading, Loading and Transport of Caliche and Sterile to heap leaching. Pampa Blanca Mine is authorized to operate at a rate of 7,000,000 tons / year.

Once heaps have been charged, the caliche wetting stage begins. Heaps are irrigated with different solutions (water and recirculated process solution) from operations centers during approximately a year. When Heaps start to drain, iodine rich brine is pumped to Iodide plant.

The brine sent to the plant is treated to produce iodide rich solution. This product is sent to iodine plant located at Pedro de Valdivia or Nueva Victoria. Subsequently, the poor iodine brine that comes out from Iodide plant, one part is alkalized and pumped to Evaporation solar pond and the second part in returned to leaching process to irrigate heaps.

The last stage of the Pampa Blanca Process, Evaporation Solar Ponds, produces high nitrate salts. This product is harvested, storaged and sent to SQM Coya Sur facility for further refinement prior to sale.

The flowchart shows the overall process to produce iodine and salts with high nitrate content, see Figure 14-2.

Figure 14-2. General diagram of the block process for the treatment of caliche ore at the Pampa Blanca processing plant.

image_115.jpg
Mining waste from operations consists of heap leaching landfills, overload, and waste salts. The mining process involves the extraction, loading and transportation of caliche according to the following stages:

Elimination of chusca (surface layer approximately 50 cm thick) and overload (intermediate layer of 50 cm to 2 m thick) using harvester tractors, which deposit them in nearby sectors already extracted or lacking minerals.
Extraction of caliche with explosives and/or mining equipment at a maximum rate of 7,000,000 tons/year.
Caliche loading, using front loaders, and transfer of ore to leaching piles, using high tonnage trucks (50, 65 or 100 tons).

14.1.1 Heap Leaching:
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Heaps are constructed on non-mineralized ground, so as not to cover valuable caliche resource. The land is prepared prior to construction of the heap leaching pads. The soil is left with a slope profile of 1 to 4%, to promote gravity flow of the drained solution. The base is covered with an impermeable geomembrane (PVC, or HDPE) to prevent seepage of leaching solutions into the ground, allowing the solutions to be collected at the toe of the heap. A protective 40-50 cm thick layer of fine material (non-mineralized chusca (weathered material) or spent leached caliche) is spread over geomembrane to protect it against being damaged by the transit of mine vehicles or punctured by sharp stones.
The caliche to be leached is then emplaced over the protective layer. The heap is constructed with a rectangular base and heights between 6 to 15 m and a crown area of 65,000 m². Once the stacking of caliche is complete, heap is irrigated to dissolve the soluble mineral salts present in the caliche.
The heap leaching operation applies alternating cycles of irrigation and resting. The irrigation system used incorporates both sprinklers and drip irrigation. The heap leaching process typically takes around 350 days from start to finish (in general, the operating range is of approximately 300- 500 days for each heap). Over the leaching cycle, the removal of soluble mineral salts results in a 15% to 20% drop in height of each leach heap.
Figure 14-3 presents a schematic of the heap leaching process. The piles are organized in such a way as to reuse the solutions they deliver production piles (the newest ones), which produce iodine rich solution to be sent to the iodide plant, and older heap whose drainage feeds the production heap. At the end of its irrigation cycle, an (old) heap leaves the system as inert debris, and a new heap enters at the other end, thus forming a continuous process.

Figure 14-3. Schematic process flow of caliche leaching

image_116.jpg
The stages in the heap leaching process (Figure 14-3) are as follows:
1.Heap Impregnation Stage : corresponds to the initial irrigation of the leach pile with industrial water. During this stage the heap begins generating salt-bearing leach solution at its base, termed brine. Stage 1 lasts about 50-70 days.
2.Irrigation Stage: During 190-280 days the heap is irrigating with Pregnant leaching solution (PLS) or iodine rich Brine. After that, the heap is irrigated with a mixture of recirculated AFA and referred to by SQM as BF and industrial water during aprox. 60-80 days.
3.Final Stage: final water irrigation of the heap with industrial water to maximize total extraction of soluble salts. This stage lasts about 20-30 days.
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The PLS obtained during heap leaching process is referred to as brine by the operation. The leaching solutions (brines) which drain from the heaps leaching are piped, according to their chemical quality to poor solution, intermediate solution, and rich brine solution storage ponds (accumulation ponds) at the COM. From here they are piped to Iodide plant.

14.1.2 Iodide Plant

SQM's leaching facilities located in mining areas are used to obtain brine, which is transported through pipelines to the iodide plant's existing facilities. The iodide plant process generates a concentrated solution of iodide, which is sent to SQM's iodine plants, followed by a residual stream of brine feble (BF), a solution of low iodine concentration. The brine Feble generated is reused in two processes: a) part was recirculated to the Operation Center (COP) located in the mining areas for the leaching process in piles, and b) the remaining fraction is sent to the solar evaporation pools after alkalization with lime or sodium carbonate.

The main equipment or infrastructure for iodide production is as follows:
SO2 generation system.
Absorption towers with their respective tanks.
Solvent extraction plants (SX) and their tanks.
Brine storage ponds with their respective pumps.

For the storage of inputs, there were:
Sulphur reserves.
Paraffin tank
Sulfuric acid tank
Sodium Hydroxide Tank
Fuel tanks
Figure 14-4. Iodide Plant Process Diagram
image5.jpg

14.1.3 Florencia evaporation solar Ponds

Evaporation solar ponds is a functional unit involving Brine preconcentration, control pond, production, harvest and transport High grade Nitrate salts (see Figure 14-5). The fundamental purpose of the ponds is to evaporate part of the feed water, separate the residual salts (sodium chloride, magnesium, and sodium sulfates) and harvest the salts with a high degree of sodium nitrate (NaNO3).

When the precipitate of the high-nitrate salt is ready, the salt is harvested, storaged and sent to SQM Coya Sur facility for further refinement prior to sale.

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The following facilities were in the area:

Alkalization: unit responsible for alkalizing BF with a lime suspension (sodium carbonate can also be used). For neutralization, a slurry preparation system can be used. Neutralization takes place in mixing tanks that discharge into ponds that have the function of decanting insoluble gypsum and lime. The neutralized and clarified solution is finally fed into the solar evaporation circuit.

Solar evaporation ponds: The processing unit is divided into pre-concentration ponds, control pond and production ponds. The preconcentration ponds are where waste salts precipitate that are harvested and placed in the residual salt reserves, with an impermeable base that allows the recovery of the impregnation solution. Nitrate salts precipitated in production pools are harvested and stored in product stockpiles.

Figure 14-5 Expansion of the Evaporation Pools plan at the Florencia Pampa Blanca Plant.

image_117.jpg
14.2.PRODUCTION SPECIFICATIONS AND EFFICIENCIES

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14.2.1 Process Criteria

Table 14-1 contains a summary of the main criteria for the Pampa Blanca processing circuit.

Table 14-1 Summary of process criteria. Mine site caliche heap leaching and productive iodine process.
Criteria
Mining Capacity and Grades
Caliche Mine Exploitation4 to 7 Mtpy
Exploitation of Future Proven Areas12 Mtpy
Average Grades
5.4 % Nitrate ; 392 ppm Iodine
Availability / Use of Availability
Mining Exploitation Factor80 - 90 %
Plant Availability Factors96.7%
Caliche Iodine PO Factor
3.7 Mt Caliche per Ton of Prilled Iodine
Caliche Nitrate PO Factor
56 Tonnes Caliche / Nitrate Salts
Caliche Iodine Iris Factor
Heap Leaching
Impregnation Stage300 to 500 Days for Each Heap
Intermediate Solution
Mixed Irrigation Stage
Washing Stage with Industrial Water
Criteria
Heap Leaching
Water + AFA Mixed Irrigation40% Dilution of AFA
Heap Drainage250 to 450 days
Iodate Brine Turbidity<150 NTU
Yield and Plant Capacity
Iodate / Iodide Yield92 - 95%
Iodide / Iodine Yield98%
Production Capacity at Pampa Blanca
1.5 Ktpy Iodide at Pampa Blanca
Iodine Prill Product Purity99,8%
High - Nitrate Salts Production Capacity
140 ktpy


14.2.2 Solar Pond Specifications
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The specific criteria for the operation of evaporation ponds are summarize in Table 14-2:
Table 14-2 Description of Inflows and Outflows of the Solar Evaporation System
System Input FlowsUnitValue
AFA Feed Flow
m3 / h
85
Sodium Nitrate (NaNO3)
g/l155
Potassium (K)11.0
Potassium Perchlorate (KClO4)
1.2
Magnesium (Mg)17
Boron w/boric acid (H3BO3)
6.8
System outflowsUnitValue
Discard SaltsTon/año60,000
Sodium sulfate%75
Sodium Chloride%25
High Nitrate Salt ProductionTon/año180,000
Sodium Nitrate (NaNO3)
75,000
Sodium Nitrate (NaNO3)
%41.9
Potassium Nitrate (KNO3)
3.0
Potassium Perchlorate (KClO4)
0.22
Magnesium (Mg)0.8
Boron w/boric acid (H3BO3)
0.8


14.2.3 Production Balance and Yields
Pampa Blanca reopened its operations in the second half of 2022 with a cargo equivalent to 4.5 million tons per year, with an iodine equivalent production of 1,130 tons/year. Iodine production began in March 2023. During 2024, the Pampa Blanca processes operated continuously, from the mine, leaching, iodide plant and evaporation ponds.

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Table 14-3 presents a summary of 2024 iodine and nitrate production at Pampa Blanca
Table 14-3 Summary of 2024 Iodine and Nitrate at Pampa Blanca
Iodine Balance PBUnitTotal Year 2024
Caliche ProcessedMt5.3
Caliche Nitrate Grade%5.8%
Caliche Iodine Gradeppm455
Iodine Heap Yield%57%
Brine sent to plant
Mm3
2,218
Concentrationgpl0.62
Iodide Produceton1,263
Iodine Plant Yield%98.3%
Iodine Producedton1,263
Iodide Plant Yield%95%
Iodide Global Yield%53%
Nitrate Balance PBUnitTotal Year 2023
AFA Sent to Evaporation Ponds
km3
672
Nitrate in AFA Sent to Evaporation Ponds
Ton NaNO3
101
Nitrate Concentration in AFA Sent to Evaporation Pondsg/l (ppt)151
NaNO3 Grade
%NA
Yield of NaNO3 from Evaporation Ponds
39.56%

14.2.4Production Estimation=>Plan Industrial P. Crovetto
In terms of future, Pampa Blanca Mining (see Section 13.2, see Table 13-3) and industrial plan, an economic analysis of which is discussed later in Chapter 19 (see Table 19-1) considers caliche extraction at a current rate of 5.5 Mtpy and estimates an increase in iodine and nitrate production to the year 2040.
Table 14-4 shows that to achieve the committed production it is required to increase water consumption to 0.47 m3/ton for the years 2025-2040 and the heap leach yield for iodine must be increased to 74%.

The indicated yield values for each year have been calculated using empirical yield ratios as a function of soluble salt content, nitrate grade and unit consumption.

Table 14-4 Pampa Blanca Process Plant Production Summary.

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Parameter2025202620272028202920302031-2040Total
Mass of Caliche ore Processed (Mt)5.55.55.55.55.55.552.385.3
Water Consumption (m3 / Ton Caliche)
0.450.470.470.470.470.470.470.47
Ore Grade (ppm, I2)
450437422416409399374392
Ore Grade (Nitrate, %)7.0%7.0%7.0%6.0%6.0%6.0%5.0%5.4%
Soluble Salts, %50.9%51.3%47.6%45.0%46.5%44.5%46.0%46.6%
Yield process to produce prilled Iodine, %72.0%72.0%72.0%71.0%70.0%70.0%67.0%69.0%
Yield process to produce Nitrates, %35.0%35.0%34.0%34.0%33.0%33.0%33.0%33.3%
Prilled Iodine produced (kt)1.81.71.71.61.61.513.223.1
Nitrate Salts for Fertilizers (kt)1371291221171101068141,535

14.3.PROCESS REQUIREMENTS
This sub-section contains forward-looking information related to the projected requirements for energy, water, process materials and personnel for the Project. The material factors that could cause actual results to differ materially from the conclusions, estimates, designs, forecasts, or projections in the forward-looking information include any significant differences from one or more of the material factors, or assumptions, that were set forth in this sub-section including actual plant requirements that yield different results from the historical operations.
Figure 14-6 shows Pampa Blanca's production process balance. It is important to note that input quantities will depend on caliche chemical properties, as well as iodide plant operation but will not exceed those indicated in the diagram.
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Figure 14-6. Projected Water and Reagent Consumption at Pampa Blanca

image6.jpg


The balance scenario shown corresponds to the situation of treatment of 7 Mtpy of caliche with 2 ktpy of iodine production.
The following sections detail energy, water, staff, and process input consumption.


14.3.1.Energy and Fuel Requirements
14.3.1.1.Power and Energy

The electrical energy required for Pampa Blanca operations comes from self-generation of energy. Having an installed capacity of 3MW.

In 2024 Pampa Blanca power generation was 7,537.6 MWh. 1,884 m3 of diesel was used for power generation.

14.3.1.2 Fuels
The operation required 2,836 m3/y diesel was supplied by duly authorized fuel trucks for construction operation

14.3.2.Water Supply and Consumption
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Water supplies are required for basic consumption, drinking water consumption (treated and available in drums, dispensed by an external supplier) and for industrial quality work. As reported, the entire sector is supplied by an industrial water supply center located in PB.
For industrial water supply, groundwater will be extracted at an average max rate of 85 L/s, from our own wells and water purchases from third parties.

Water Consumption
Table 14-5 summarizes the rate from industrial water supply by SQM and ADASA, for the year 2024.
Table 14-5 Rates Industrial Water Supply
YearPozo Carolina (L/s)Pozo Puelma (L/s)ADASA (L/s)Total (L/s)
20246.261.476976.73
Potable water will be required to cover all workers' consumption and sanitary needs. Potable water supply considers a use rate of 100 L/person/d, of which 2 L/person/d corresponds to drinking water at the work fronts and cafeterias. Commercial bottled water will be provided to staff. Sanitary water will be supplied from storage tanks located in the camp and office sectors, which will be equipped with a chlorination system. A total of 200 workers per month are required, considering the Pampa Blanca operations together, so the total amount of potable water will be 20 m3/day (0.23 L/s).
Table 14-6 provides a breakdown of the estimated annual water requirement by potable and industrial water for year 2024. The heap leaching process corresponds to the greatest water demand.
Table 14-6 Pampa Blanca Industrial and Potable Water Consumption
ProcessAnnual Volume (M³/Year)Equivalent Rate (L/s)
Industrial Water
Heap Leach2,185,49369.3
Mine93,577.53.0
Iodide Plant34,4141.1
Neutralization Plant
Solar Evaporation Ponds11,5030.4
Total Industrial Water2,324,987.50073.7
Drinking Water690,23

14.3.3.Staffing Requirements
An estimated 154 workers are required during Pampa Blanca operations, Table 14-11 summarizes current workforce requirements.

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Table 14-11 Personnel Required by Operational Activity

Operational ActivityPampa Blanca
Caliche Mining99
Maintenance (mine-plant-SEP)28
Iodide Production14
Evaporation System-Operations13
Total154

Process Plant Consumables
Raw materials such as sulfur, chlorine, paraffin, sodium hydroxide, or sulfuric acid, are added to the plants to produce a concentrated iodide solution which is then used in iodine production. These materials are transported by trucks from different parts of the country. A-412, which connects with Route 5, is the main route for vehicular flows required for input supply and raw material shipment.
Reagent Consumption Summary
Table 14-12 summarizes the main annual materials required for Pampa Blanca's operations to the nominal production rate of 2 kt iodine prill. It is worth noting that some of the inputs can be replaced by an alternative compound; for example, sulfur can be replaced by liquid sulfur dioxide, kerosene can be replaced by sodium hydroxide and finally, lime can be replaced by sodium carbonate.
It is important to note that there are ranges of consumption factors that have been studied through historical operational data of plant treatment. The ranges are established according to the different qualities of brine obtained from the treated resource. These factors allow projecting the requirements of reagents and process inputs, both for annual, short- and long-term planning.

Table 14-12 Process Reagents and Consumption Rates per Year, PB
Reagent and ConsumablesFunction or Process AreaUnitsPampa Blanca 2,000 ton Prill
Ammonium NitrateNecessary for BlastingTpy2,600
Sulfuric AcidIodide PlantTpy4,070
SulfurIodide And Iodine PlantsTpy2,205
Liquid Sulfur DioxideUsed as an Alternative to Solid SulfurTpy3,965
KeroseneAt The Iodide Plant as a SolventTpy1,620
Sodium HydroxideAt the Iodine Plants and at the Iodide Plant as Replacement of KeroseneTpy3,005
ChlorineSupply Chlorine to the Iodine Plants as an OxidizerTpy205
Filter AidAlpha Cellulose Powder used to Iodide and Iodine PlantsTpy9
Lime (95 % Cao)Neutralization Plant for Lime ReplacementTpy825
Sodium CarbonateNeutralization Plant for Lime ReplacementTpy150
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Reagent handling and storage
To operate, inputs used are stored in stockpiles and tanks, facilities available in the area known as the input reception and storage area. To store the inputs used in the Pampa Blanca plant, the following infrastructure are used:
1.Sulfur storage facilities.

2.Kerosene tank

3.Sulfuric acid tank

4.Diesel oil tanks.

5.Caustic soda tank.
Each reagent storage system assembly is segregated based on compatibility and is located within curbed containment areas to prevent spill spreading and incompatible reagents from mixing. Drainage sumps and pump sumps are provided for spill control.
14.4.QUALIFIED PERSON´S OPINION

According to Gino Slanzi Guerra, QP responsible for metallurgy and resource treatment:

Metallurgical test data on the resources planned to be processed in the projected production plan to 2022 indicate that recovery methods are adequate. The laboratory, bench and pilot plant scale test programmed conducted over the last few years has determined that feedstock is reasonably suitable for production and has demonstrated that it is technically possible using plant established separation and recovery methods to produce iodine and nitrate salts. Based on this analysis, the most appropriate process route, based on test results and further economic analysis of the material, are the unit operations selected which are otherwise typical for the industry.

In addition, historical process performance data demonstrates reliability of recovery estimation models based on mineralogical content. Reagent forecasting and dosing will be based on analytical processes that determine mineral grades, valuable element content and impurity content to ensure that system treatment requirements are effective. Although there are known deleterious elements and processing factors that can affect operations and products, the company has incorporated proprietary methodologies for their proper control and elimination. These are supported by the high level of expertise of its professionals, which has been verified at the different sites visited.

The mineralogical, chemical, physical and granulometric characterization results of the mineral to be treated, obtained from trials obtained, allow continuous evaluation of processing routes, either at the initial conceptual stages of the project or during the process already established, in order to ensure that the process is valid and in force, and/or to review optimal alternatives to recover valuable elements based on resource nature. Additionally, analysis methodologies determine deleterious elements, in order to establish mechanisms in operations so that these can be kept below the limits to ensure a certain product quality.
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15 PROJECT INFRASTRUCTURE

This section contains forward-looking information related to locations and designs of facilities comprising infrastructure for the Project. The material factors that could cause actual results to differ materially from the conclusions, estimates, designs, forecasts, or projections in the forward-looking information include any significant differences from one or more of the material factors or assumptions that were set forth in this sub-section including Project development plan and schedule, available routes and facilities sites with the characteristics described, facilities design criteria, access, and approvals timing.

Pampa Blanca's infrastructure analysis considers the existing facilities and the requirements associated with future projects. This section describes both the existing facilities and planned expansion projects.

The Pampa Blanca mine is located at Sierra Gorda, province of Antofagasta, Antofagasta Region, approximately 100 km northeast of the city of Antofagasta. It is accessed by Highway 5 North. These works as a whole involve a surface area of approximately 104.4 km2. The geographical reference location is 7,438,578 N, 434,651 E, with an average elevation of 1.353 m.a.s.l.

Figure 15-1 shows Pampa Blanca's geographic location. It also shows, for reference purposes, other sites belonging to SQM (Nueva Victoria, Coya Sur, Salar de Atacama, and Salar del Carmen), and facilities used to distribute its products (Port of Tocopilla, Port of Antofagasta, and Port of Iquique).

In February 2010, mining operations in Pampa Blanca were halted, with the subsequent temporary closure of the site.

In 2021, SQM makes the decision to reactivate the operations of the Pampa Blanca project, to develop a productive strategy to face the future growing demand for iodine and nitrate, and to be able to cover the expected growth.

Strengthen the supply of iodine, reactivating the operations of the Iodide Plant of the Pampa Blanca Project in the II Region (Antofagasta) to produce 1,000 tons of iodine and 70,000 tons of nitrates per year.

Since November of 2023 the Pampa Blanca mine had been running as expected.

The Pampa Blanca expansion project aims to incorporate new mine areas for iodide, iodine, and nitrate-rich salts production at Pampa Blanca mine, which will increase the total amount of caliche to be extracted and the use of the sea water for these processes. This project consists in modifying Pampa Blanca mine, which consists of:

New mine areas (115 Km2 ), with a caliche extraction rate of 12 Mtpy
One new Iodide production plants to increase on 3,000 tpy the production
One new iodine production plant (7,000 tpy) for a total of 7,000 tpy
New evaporation ponds to produce nitrate-rich salts (470,000 tpy)
New operational irrigation centers and distribution pipe solutions which should cover the new mine area
New truck workshops and supporting infrastructure such as roads, casinos, offices, control rooms, etc.
A new neutralization system
A Construction of a seawater adduction pipeline from Mejillones Bay to the mining area, to meet the water needs during the operation phase, with a maximum flow of up to 1,950 L/s
Connection of the industrial areas of the Project to the Norte Grande Interconnected System (SING), to provide sufficient energy for their electrical requirements

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Figure 15-1. General Location Project Pampa Blanca
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Figure 15-2. General Location of Pampa Blanca Expansion Project

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15.1.ACCESS TO PRODUCTION, STORAGE AND PORT LOADING AREAS

General access to the Project, suitable for all types of vehicles, is near the 1,463 kilometer point of Route 5 that connects with a private road of SQM.

SQM's products and raw materials are transported by trucks, which are operated by third parties under long-term, dedicated contracts.

15.2.PRODUCTION AREAS AND INFRASTRUCTURE

The main facilities of the Pampa Blanca production area are as follows:

Caliche extraction mine.
Mine Maintenance workshop.
Industrial water supply.
Leaching
Iodide plants.
Evaporation ponds.
Offices.
Domestic waste disposal site.
Hazardous Waste Yard.
Non-hazardous industrial waste

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Figure 15-3. Status of the Plant Pampa Blanca
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The Pampa Blanca mining areas and process facilities are described in more detail below.


15.2.1 Mine
Caliche ore is blasted and dug at Pampa Blanca. The minimum thickness of caliche ore that SQM will mine is 1.5 m. The ore deposits are mined on a 25 x 25 m grid pattern.

The surface area authorized for mining at Pampa Blanca is 52.4 km2.

The following sectors are in the mine:
Exploitation and earthmoving sectors.
Roads
Powder magazine and silos for ammonium nitrate storage.
Maintenance workshop
General services staff facilities
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Figure 15-4. Truck Workshop.
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Figure 15-5. Temporary Industrial waste storage yard.
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15.2.2 Leaching
The Leaching facility inside the mine area comprises the following areas:
Heap Leaching
Mine Operation Centers (COM)
Auxiliary facilities

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Heap leaching
They correspond to caliche accumulation cakes in the shape of a pyramidal trunk, with a rectangular base, and a leachate collection system.
They correspond to caliche accumulation platform (normally area of 40,000 - 65,000 m2.) in the shape of a pyramidal trunk, with a rectangular base, with bottom waterproofed with HDPE membranes. They are loaded with required caliche (between 0.5 a 1.0 Mt, with heights between 7 to 15 m) and are irrigated with different solutions (Industrial Water, Industrial water + BF mix or Intermediate Solution) with a leachate collection system.
Mine Operation Centers (COM)
The COMs include the facilities associated with a set of leach heaps. The COMs have brine accumulation ponds (poor solution, intermediate and rich solution ponds), recirculated feble brine ponds, industrial water ponds, and their respective pumping and impulsion systems. COM locations are defined according to mine planning.
Auxiliary facilities
General service staff facilities.

Figure 15-6. Operation Center.
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15.2.3 Iodide Plant
The Iodide Plant facility has the following areas:
Iodide Plant
Auxiliary facilities

Iodide Plant
The principal equipment or infrastructure for iodide production includes the following:
Storage ponds to hold the brine received from the heap leaching operation
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Furnaces for SO2 generation
Absorption towers with their respective tanks
Gas scrubbing system
Stripping System
Solvent extraction plants (SX) and their tanks
Brine feble wells with their respective pumps

Auxiliary facilities
The following facilities are available for the storage of consumables used in the iodide plant:
Sulfur stockpile ponds
Kerosene tanks
Sulfuric acid tanks
Diesel stroga tanks
Water pond
Ponds with intermediate process solutions

The following facilities are in the plant sector:
Fire Network System: water storage tank with its respective pump and piping system distributed throughout the plant installation.
Generator room.
Compressor room.
Electrical rooms.
Control room.
Maintenance workshop and yard for materials and spare parts.

Ancillary facilities
Correspond to:
Offices
Warehouses
Exchange office
Polyclinic
Casino
Temporary waste storage yard
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Figure 15-7. Iodide Plant
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Figure 15-8. Iodide Plant
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15.2.4 Evaporation Ponds
A solar evaporation plant is a functional unit that involves solution conditioning (neutralization of brine feble generated by the Iodide Plant), ponds, transfers, and salt harvesting and conveying systems. The principal purpose of the ponds is to evaporate all the feed water, separate the waste salts (sodium chloride, magnesium, and sodium sulfates), and harvest the salts with high sodium nitrate (NaNO3) grade.
The harvested waste salts are stored in a salt disposal field. The nitrate-rich production salts are stored in the final product storage area.
The following facilities are in the area:
Neutralization Plant.
Solar evaporation ponds.
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Auxiliary installations.
Neutralization Plant
The BF is neutralized with a lime slurry (sodium carbonate can also be used). For neutralization, there are slurry preparation plants. Neutralization takes place in mixing tanks that discharge into ponds that have the function of decanting the gypsum and lime insoluble. The neutralized and clarified solution is then fed to the solar evaporation circuit.
Figure 15-9. Neutralization Plant.

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Solar Evaporation Ponds
This is divided into pre-concentration ponds, production ponds, and purge ponds and cover an approximate area of 630,000 m2. In the pre-concentration ponds, discard salts precipitate, which is harvested and placed in the discard salts stockpiles, which have a waterproofed base that allows the recovery of the stripping or impregnation solution. Nitrate-rich salts precipitate in the production ponds and are harvested and stockpiled in product ponds, which are then shipped by truck to Coya Sur in the Antofagasta Region or other SQM plants or third parties.

Auxiliary facilities
In the area, there are offices, bathrooms, dressing rooms, and a casino for the staff working in the area and TAS plant.









Figure 15-10. Solar Evaporation Pools.
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Figure 15-11. Solar Evaporation Pools.
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15.3.COMMUNICATIONS

The facilities have telephone, internet, and television services via satellite link or by fiber optics supplied by an external provider.

Communication for operations staff is via communication radios with the same frequency.

Communication to the control system, CCTV, internal telephony, energy, and data monitoring is via its own fiber optics, which connects process plants and control rooms.

15.4.WATER SUPPLY

Industrial water is supplied by groundwater extraction ponds and third-party suppliers. A network of pipelines, pumping stations, and power lines are used to extract, pump, transport, and distribute industrial water to the different points where it is required.

15.5.WATER TREATMENT

The project has 3 water treatment plants that process workers' wastewater

Table 15-1. Approved Water treatment unit by Sector

Plant AreaCapacity [persons]Capacity [Liters/day]Approved resolution
Iodide Plant5011,250 l/dRES. Ex. N° 2302298535
Neutralization Plant255,625 l/dRES. Ex. N° 2302298523
Truck Workshop 10015,000 l/dRES. Ex. N° 2302298541
15.6.POWER SUPPLY

Pampa Blanca has its own power supply system, that is not connected to the National Electric System. The supply systems consist on 4 diesel generators of 1 MVA each one with an electrical Substation of 3 MVA 0.380/23 kV that distributes energy through a 23 kV MT line to the different areas.

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Figure 15-11. Force House
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16 MARKET STUDIES
This section contains forward-looking information related to commodity demand and prices for the Project. The material factors that could cause actual results to differ materially from the conclusions, estimates, designs, forecasts, or projections in the forward-looking information include any significant differences from one or more of the material factors or assumptions that were set forth in this section including prevailing economic conditions, commodity demand and prices are as forecasted over the Long-Term period.
16.1 IODINE AND ITS DERIVATIVES
16.1.1The Company
Iodine and iodine derivatives are used in a wide range of medical, agricultural, and industrial applications as well as in human and animal nutrition products. They are mainly used in the X-Ray contrast media, polarizing film and pharmaceuticals.
Industrial chemicals have a wide range of applications in certain chemical processes such as the manufacturing of glass, explosives and ceramics. Industrial nitrates are also being used in concentrated solar power plants as a means for energy storage.

Iodine and its Derivatives: We believe that we are the world’s leading producer of iodine and iodine derivatives, which are used in a wide range of medical, pharmaceutical, agricultural and industrial applications, including X-Ray contrast media, polarizing films for LCD and LED, antiseptics, biocides and disinfectants, in the synthesis of pharmaceuticals, electronics, pigments and dye components.

Industrial Chemicals: We produce and sell three industrial chemicals: sodium nitrate, potassium nitrate and potassium chloride. Sodium nitrate is used primarily in the production of glass, explosives, and metal treatment, metal recycling and the production of insulation materials, among other uses. Potassium nitrate is used in the manufacturing of specialty glass, and it is also an important raw material for the production of frits for the ceramics, enamel industries, metal treatment and pyrotechnics. Solar salts, a combination of potassium nitrate and sodium nitrate, are used as a thermal storage medium in concentrated solar power plants. Potassium chloride is a basic chemical used to produce potassium hydroxide, and it is also used as an additive in oil drilling as well as in food processing, among other uses.

Table 16-1. Percentage Breakdown of SQM's Revenues for 2024, 2023 and 2022
Revenue breakdown202420232022
Specialty Plant Nutrition21%12%11%
Lithium and derivatives49%69%76%
Iodine and derivatives21%12%7%
Potassium6%4%4%
Industrial chemicals2%2%2%
Other products and services1%—%—%
Total100%100%100%

16.1.2Business Strategy
Iodine and its Derivatives

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Our strategy in our iodine business is to (i) encourage demand growth and promote new uses for iodine; (ii) provide a product of consistent quality according to the requirements of the customers; (iii) build a local and trustful relationship with our customers through warehouses placed in every major region; (iv) to achieve and maintain sufficient market share to optimize our cost and the use of the available production capacity; (v) participate in the iodine recycling projects through the Ajay-SQM Group (“ASG”), a joint venture with the US company Ajay Chemicals Inc. (“Ajay”) and reduce the production costs through improved processes and increased productivity to compete more effectively.

Industrial Chemicals

Our strategy in our industrial chemical business is to: (i) maintain our leadership position in the industrial nitrates market; (ii) encourage demand growth in different applications as well as exploring new potential applications; (iii) position ourselves as a long-term, reliable supplier for the e industry, maintaining close relationships with R&D programs and industrial initiatives; (iv) reduce our production costs through improved processes and higher productivity in order to compete more effectively and (v) supply a product with consistent quality according to the requirements of our customers.

16.1.3 Main Business Lines

16.1.3.1Iodine and its Derivatives

We believe that we are the world’s largest producer of iodine. In 2024, our revenues from iodine and iodine derivatives amounted to US$968.3 million, representing 21.4% of our total revenues in that year and an increase from US$892.2 million in 2023. This increase was mainly attributable to higher sales volumes than in 2023. Average iodine prices were approximately 2.3% lower in 2024 than in 2023. Our sales volumes increased approximately 11.1% in 2024. We estimate that our sales accounted for approximately 37% of global iodine sales by volume in 2024.
The following table shows our total sales volumes and revenues from iodine and iodine derivatives for 2024, 2023 and 2022:
Table 16-2. Iodine and derivatives volumes and revenues, 2022 - 2024
Sales volumes
(Thousands of metric tons)
202420232022
Iodine and derivatives14.513.112.7
Total revenues
(In US$ millions)
968.3892.2754.3

16.1.3.1.1 Market

Iodine and iodine derivatives are used in a wide range of medical, agricultural and industrial applications as well as in human and animal nutrition products. Iodine and iodine derivatives are used as raw materials or catalysts in the formulation of products such as X-ray contrast media, biocides, antiseptics and disinfectants, pharmaceutical intermediates, polarizing films for LCD and LED screens, chemicals, organic compounds and pigments. Iodine is also added in the form of potassium iodate or potassium iodide to edible salt to prevent iodine deficiency disorders.

X-ray contrast media is the leading application of iodine, accounting for approximately 37% of demand. Iodine’s high atomic number and density make it ideally suited for this application, as its presence in the body can help to increase contrast between tissues, organs, and blood vessels with similar X-ray densities. Other applications include pharmaceuticals, which we believe account for 13% of demand; LCD and LED screens, 13%; iodophors and povidone-iodine, 6%; animal nutrition, 7%; fluoride derivatives, 6%; biocides, 5%; nylon, 3%; human nutrition, 3% and other applications, 7%.

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In 2024, our estimates indicate that the market experienced an upturn of approximately 7% compared to the previous year. This expansion can primarily be attributed to a series of key factors impacting various industries. First, the broader global economic recovery has led to a better-than-expected GDP this year, with industrial production boosting company investments, especially in India and China. Additionally, demand for contrast media has accelerated due to significant expansions and strong performance among major players in this industry, where government expenditures in healthcare and new technologies have played a key role. Finally, while high prices have slowed demand in certain sectors, such as iodophors and biocides, the decline in these applications was smaller than the growth seen in other industries, leading to a strong iodine demand.

Conversely, the demand for X-ray contrast media emerged as a primary driver of growth in the iodine market. This increase is largely due to heightened healthcare expenditures, increased prevalence of chronic diseases necessitating diagnostic imaging, rising volume of CT procedures, advancements in imaging technology and demographic shift towards an aging population. The growing use of diagnostic imaging, particularly in China, Europe and the US, has significantly bolstered the demand for iodine-based contrast agents, counterbalancing some of the declines seen in other sectors.

16.1.3.1.2 Products

We produce iodine in our Nueva Victoria plant, near Iquique, Chile, Pedro de Valdivia plant and in our newest addition, Pampa Blanca mining site, both located close to María Elena, Chile. We have a total production capacity of approximately xx metric tons per year of iodine.

Through Ajay SQM Group (“ASG”), we produce organic and inorganic iodine derivatives. ASG was established in the mid-1990s and has production plants in the United States, Chile and France. ASG is one of the world’s leading inorganic and organic iodine derivatives producer.

Consistent with our iodine business strategy, we are constantly working on the development of new applications for our iodine-based products, pursuing a continuing expansion of our businesses and maintaining our market leadership.

We manufacture our iodine and iodine derivatives in accordance with international quality standards and have qualified our iodine facilities and production processes under the ISO 9001:2015 program, providing third party certification of the quality management system and international quality control standards that we have implemented.


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16.1.3.1.3 Marketing and Customers
In 2024, we sold our iodine products in approximately 33 countries to 131 customers, and most of our sales were exports. Two customers individually accounted for at least 10% of sales in this segment, representing approximately 33% of iodine sales. The 10 largest customers together accounted for approximately 77% of sales during this period. On the other hand, no supplier had an individual concentration of at least 10% of the cost of sales of this line of business.
The following table shows the geographical breakdown of our revenues:
Table 16-3. Geographical Breakdown of the Revenues: Iodine and its derivatives
Revenues Breakdown202420232022
North America16%14%19%
Europe38%41%38%
Chile0%0%0%
Central and South America (excluding Chile)2%2%2%
Asia and Others43%42%41%

We sell iodine through our own worldwide network of representative offices and through our sales, support and distribution affiliates. We maintain inventories of iodine at our facilities throughout the world to facilitate prompt delivery to customers. Iodine sales are made pursuant to spot purchase orders or within the framework of supply agreements. Supply agreements generally specify annual minimum and maximum purchase commitments, and prices are adjusted periodically, according to prevailing market prices.


16.1.3.1.4 Competition

The world’s main iodine producers are based in Chile, Japan and the United States. Iodine is also produced in Russia, Turkmenistan, Azerbaijan, Indonesia and China.

Iodine is produced in Chile from a unique mineral known as caliche ore, whereas in Japan, the United States, Russia, Turkmenistan, Azerbaijan, and Indonesia, producers extract iodine from underground brines that are mainly obtained together with the extraction of natural gas and petroleum. The recycled iodine waste production comes mainly from China and Japan.

Five Chilean companies accounted for approximately 60% of total global sales of iodine in 2024, including SQM, with approximately 37%, and four other producers accounting for the remaining 23%. The other Chilean producers are S.C.M. Cosayach (Cosayach), controlled by the Chilean holding company Inverraz S.A.; ACF Minera S.A., owned by the Chilean Urruticoechea family; Algorta Norte S.A., a joint venture between ACF Minera S.A. and Toyota Tsusho; and Atacama Minerals, which is owned by Chinese company Tewoo.

We estimate that eight Japanese iodine producers accounted for approximately 23% of global iodine sales in 2024, including recycled iodine.

We estimate that iodine producers in the United States accounted for nearly 5% of world iodine sales in 2024.

Iodine recycling is a growing trend worldwide. Several producers have recycling facilities where they recover iodine and iodine derivatives from iodine waste streams.

We estimate 16% of the iodine supply comes from iodine recycling. Through ASG or alone, we are also actively participating in the iodine recycling business using iodinated side-streams from a variety of chemical processes in Europe and the United States.

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The prices of iodine and iodine derivative products are determined by market conditions. World iodine prices vary depending upon, among other things, the relationship between supply and demand at any given time. Iodine supply varies primarily as a result of the production levels of the iodine producers (including us) and their respective business strategies. In 2024, our annual average iodine sales prices slightly decreased compared to 2023, reaching approximately US$67 per kilogram in 2024, from the average sales prices of approximately US$68 per kilogram observed in 2023.

Demand for iodine varies depending upon overall levels of economic activity and the level of demand in the medical, pharmaceutical, industrial and other sectors that are the main users of iodine and iodine-derivative products. Certain substitutes for iodine are available for certain applications, such as antiseptics and disinfectants, which could represent a cost-effective alternative to iodine depending on prevailing prices.

The main factors of competition in the sales of iodine and iodine derivative products are reliability, price, quality, customer service and the price and availability of substitutes. We believe we have competitive advantages compared to other producers due to the size and quality of our mining reserves and the available production capacity. We believe our iodine is competitive with that produced by other manufacturers in certain advanced industrial processes. We also believe we benefit competitively from the long-term relationships we have established with our largest customers.


16.1.3.2 Industrial Chemicals
In 2024, our revenues from industrial chemicals were US$78.2 million, representing approximately 1.7% of our total revenues for that year and a 55.4% decrease from US$175.2 million in 2023, as a result of higher sales volumes in this business line, which offset lower sales prices. Sales volumes in 2024 decreased 70.9% compared to sales volumes reported last year, while average prices in the business line increased 53.1% during 2024 compared to average prices reported during 2023.
The following table shows our sales volumes of industrial chemicals and total revenues for 2024, 2023 and 2022:
Table 16-4. Industrial chemicals volumes and revenues, 2022 - 2024
Sales volumes
(Thousands of metric tons)
202420232022
Industrial Chemicals 52.6180.4147.0
Total revenues
(In US$ millions)
78.2175.2165.2

16.1.3.2.1 Market

Industrial sodium and potassium nitrates are used in a wide range of industrial applications, including the production of glass, ceramics and explosives, metal recycling, insulation materials, metal treatments, thermal solar and various chemical processes.

We are also experiencing a growing interest in using solar salts in thermal storage solutions related to CSP technology. Due to their proven performance, solar salts are being tested in industrial heat processes and heat waste solutions. These new applications may open new opportunities for solar salts uses in the near future, such as retrofitting coal plants.

16.1.3.2.2 Products

We produce and sell three industrial chemicals: sodium nitrate, potassium nitrate and potassium chloride. Sodium nitrate is used primarily in the production of glass, explosives, metal treatment, metal recycling and the production of insulation materials, adhesives, among other uses. Potassium nitrate is used in the manufacturing of specialty glass, and it is also an important raw material for the production of frits for the ceramics, enamel industries, metal treatment and pyrotechnics. Solar salts, a combination of potassium nitrate and sodium nitrate, are used as a thermal storage medium in concentrated solar power plants. Potassium chloride is a basic chemical used to produce potassium hydroxide, and it is also used as an additive in oil drilling and in food processing, among other uses.
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In addition to producing sodium and potassium nitrate for agricultural applications, we produce different grades of these products, including prilled grades, for industrial applications. The grades differ mainly in their chemical purity. We have operational flexibility in producing industrial grade nitrates, because they are produced from the same process as their equivalent agricultural grades, needing only an additional step of purification. We may, with certain constraints, shift production from one grade to the other in response to market conditions. This flexibility allows us to maximize yields and to reduce commercial risk. In addition to producing industrial nitrates, we produce, market and sell industrial-grade potassium chloride.

16.1.3.2.3 Marketing and Customers
In 2024, we sold our industrial nitrate products in 53 countries, to approximately 274 customers. No single customer accounted for at least 10% of this segment's sales, and the 10 largest customers together accounted for approximately 27% of this segment's revenues. On the other hand, no supplier has an individual concentration of less than 10% of the cost of sales of this line of business.. We make lease payments to Corfo which are associated with the sale of different products produced in the Salar de Atacama, including lithium carbonate, lithium hydroxide and potassium chloride. See Note 22.2 to our consolidated financial statements for the disclosure of lease payments made to Corfo for all periods presented.
The following table shows the geographical breakdown of our revenues:
Table 16-5. Geographical Breakdown of the Revenues: Industrial chemicals
Revenues Breakdown202420232022
North America56%27%36%
Europe24%12%17%
Chile1%1%1%
Central and South America (excluding Chile)10%6%7%
Asia and Others9%54%39%

Our industrial chemical products are marketed mainly through our own network of offices, logistic platforms, representatives and distributors. We maintain updated inventories of our stocks of sodium nitrate and potassium nitrate, classified according to graduation, to facilitate prompt dispatch from our warehouses. We provide support to our customers and continuously work with them to improve our service and quality, together with developing new products and applications for our products.


16.1.3.2.4 Competition

We believe that we are one of the world’s largest producers of industrial sodium nitrate and potassium nitrate. In 2024, our estimated market share by volume for industrial potassium nitrate was 32% and for industrial sodium nitrate was 29% (excluding domestic demand in China and India).

Our competitors in sodium nitrate are mainly based in Europe and Asia, producing sodium nitrate as a by-product of other production processes. In sodium nitrate, BASF AG, a German corporation, and several producers in Eastern Europe and China are competitive since they produce industrial sodium nitrate as a by-product. Our industrial sodium nitrate grades also compete indirectly with substitute chemicals, including sodium carbonate, sodium sulfate, calcium nitrate and ammonium nitrate, which may be used in certain applications in place of sodium nitrate and are available from a large number of producers worldwide.

Our main competitors in the industrial potassium nitrate business are Haifa Chemicals, Kemapco and some Chinese producers, which we estimate had a market share of 18%, 9% and 15%, respectively, in 2024.
Producers of industrial sodium nitrate and industrial potassium nitrate compete in the marketplace based on attributes such as product quality, delivery reliability, price, and customer service. Our operation offers both products at high quality and with low cost.
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In the industrial potassium chloride market, we are a relatively small producer, mainly focused on supplying regional needs.

16.2 SPECIALTY PLANT NUTRITION

16.2.1 The Company

Specialty plant nutrients are premium fertilizers that enhance crop yields and quality. Our key product is potassium nitrate, mainly used in fertigation for high-value crops. We also produce and sell potassium chloride globally as a commodity fertilizer. Additionally, we trade other complementary fertilizers worldwide to diversify our offerings.

Specialty Plant Nutrition: We offer three main types of specialty plant nutrients for fertigation, direct soil, and foliar applications: potassium nitrate, sodium nitrate, and specialty blends. We also sell other specialty fertilizers, including third-party products. These products, available in solid or liquid forms, are mainly used on high-value crops like fruit, flowers, and some vegetables. They are widely utilized in modern agricultural techniques such as hydroponics, greenhouses, and fertigation (where fertilizer is dissolved in water before irrigation).

Specialty plant nutrients offer advantages over commodity fertilizers, such as quick absorption, excellent water solubility, and low chloride content. Potassium nitrate, a key product, comes in crystalline and prill forms for various applications. Crystalline potassium nitrate suits fertigation and foliar use, while prills are ideal for direct soil application.

We market our products under the following brands: Ultrasol® (fertigation), Qrop® (soil application), Speedfol® (foliar application), and Allganic® (organic agriculture).

Sophisticated customers now seek integrated solutions rather than single products. Our offerings include customized blends and agronomic services, enhancing plant nutrition for better yields and quality. Derived from natural nitrate compounds or potassium brines, our products feature beneficial trace elements, offering advantages over synthetic fertilizers. Consequently, specialty nutrients command a premium price compared to standard fertilizers.

Potassium: Potassium chloride is produced from brines extracted from the Salar de Atacama. This commodity fertilizer is used to nourish various crops, including corn, rice, sugarcane, soybeans, and wheat.

Other Products and Services: We sell a variety of fertilizers and blends, including those we don't produce. We are the largest producer of potassium nitrate and distributor of potassium nitrate, sulfate, and chloride.

16.2.2 Business Strategy

Specialty Plant Nutrition

Our strategy for the specialty plant nutrition business includes:

Leveraging our products' advantages over commodity fertilizers.
Expanding our sales of high-margin potassium and natural nitrate-based nutrients.
Investing in complementary businesses to enhance our product portfolio, increase production, reduce costs, and add marketing value.
Developing new nutrient blends in strategically located mixing plants.
Focusing on markets where soluble and foliar applications establish leadership.
Enhancing global distribution and marketing through strategic alliances.
Reducing production costs with improved processes and higher labor productivity.
Supplying consistently quality products tailored to customer requirements.

Potassium
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Our potassium business strategy includes:

Flexibility to offer crystallized or granular products as needed.
Targeting markets with logistical advantages and synergies with our specialty plant nutrition business.
Providing consistent quality to meet customer requirements.

16.2.3 Main Business Lines

16.2.3.1 Specialty Plant Nutrition
In 2024, specialty plant nutrients revenues decreased to US$941.9 million, representing 20.8% of our total revenues for that year and a 3.1% increase from US$913.9 million in specialty plant nutrients revenues in 2023. Prices decreased approximately 11.9% in 2024.

It is estimated that we are the largest producer of potassium nitrate globally. Our sales accounted for approximately 41% of global potassium nitrate sales for all agricultural uses by volume in 2024.

Table 16-6. Specialty Plant Nutrition volumes and revenues, 2022 - 2024
Sales volumes
(Thousands of metric tons)
202420232022
Sodium nitrate12.516.714.4
Potassium nitrate and sodium potassium nitrate534.0443.5477.4
Specialty blends276.7243.4218.0
Other specialty plant nutrients159.7136.5138.1
Total revenues
(In US$ millions)
941.9913.91,172.3


16.2.3.1.1 Market

Specialty plant nutrients serve various agricultural purposes, including fertigation for high-value crops like vegetables and fruits. These fertilizers must be highly soluble and free of impurities for modern irrigation methods such as drip and micro-sprinkler systems. Potassium nitrate stands out among these nutrients due to its chlorine-free composition, high solubility, proper pH, and lack of impurities, allowing it to command a premium price over alternatives like potassium chloride and sulfate.

Modern irrigation systems are widely used in protected crops and high-value fruit plantations like greenhouses, tunnels (for berries), and shade houses (for tomatoes). Specialty nutrients are also applied for foliar and granular soil applications in niches such as potato and tobacco production.

Specialty plant nutrients have distinct characteristics that can increase productivity and improve quality when applied to specific crops and soils. These products offer certain benefits over commodity fertilizers derived from other sources of nitrogen and potassium, such as urea and potassium chloride.

Since 1990, the international market for specialty plant nutrients has expanded at a quicker pace than the market for commodity fertilizers. Contributing factors include: (i) the adoption of new agricultural technologies like fertigation, hydroponics, and greenhouses; (ii) rising land costs and water scarcity, which have prompted farmers to enhance yields and reduce water consumption; and (iii) growing demand for higher-quality crops.

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However, during 2022 and 2023, the market for agricultural soluble potassium nitrate saw a reduction in consumption by approximately 12% and 8%, respectively, due to significant price increases, adverse climate conditions, and high inflation rates. These estimates exclude locally produced and sold potassium nitrate in China and only account for net imports and exports.

Despite two consecutive years of decline, 2024 was a good year for the Specialty Plant Nutrition market. We estimate that the market, excluding production and consumption within China, grew by around 17%, reaching levels slightly below what we had seen during 2020.

16.2.3.1.2 Products

We produce three main types of specialty plant nutrients that provide nutritional solutions for fertigation, direct soil applications and foliar fertilizers: potassium nitrate (KNO3), sodium nitrate (NaNO3) and specialty blends. We also sell other specialty fertilizers, including products produced by third parties. All of these products are used in solid or liquid form primarily on high-value crops such as fruits, flowers and some vegetables. These fertilizers are widely used in crops using modern agricultural techniques such as hydroponics, greenhouses and crops with foliar application and fertigation (in the latter case, the fertilizer is dissolved in water prior to irrigation).

Specialty plant nutrients have certain advantages over commercial fertilizers, such as fast and effective absorption (without requiring nitrification), superior water solubility, and low chloride content. One of the most important products in this business line is potassium nitrate, which is marketed in crystalline or prilled form, allowing for different application methods. Crystalline potassium nitrate products are ideal for fertigation and foliar applications, and potassium nitrate beads are suitable for direct soil applications.

Special blends are produced using our own special plant nutrients and other components in blending plants operated by us or our affiliates and related companies around the world.

The advantages of our special "Ultrasol" vegetable blends include the following:
Fully water soluble for efficient use in hydroponics, fertigation, foliar applications, and advanced agricultural techniques, reducing water usage.
Chloride-free to prevent toxicity in chlorine-sensitive crops.
Provides nitrogen in nitric form for faster nutrient absorption compared to urea- or ammonium-based fertilizers.
We have developed brands for their commercialization according to the different applications and uses of our products. Our main brands are: Ultrasol® (fertigation), Qrop® (soil application), Speedfol® (foliar application) and Allganic® (organic agriculture).

During 2024, we continued to grow sales of differentiated fertilizers such as Ultrasoline® for improved root growth and optimal nitrogen metabolism, ProP® for more efficient phosphorus absorption, and Prohydric® for more efficient fertilization and water use.

Potassium nitrate and specialty blends represent high-margin products derived from sodium nitrate feedstock. Specialty blends are created using our proprietary plant nutrients along with other components at blending facilities operated by our company and affiliates globally.

Specialty nutrients can be classified as either specialty field fertilizers or water-soluble fertilizers based on their application methods.

Specialty field fertilizers are applied directly to the soil either manually or mechanically. Their high solubility, chloride-free nature, and non-acidic reactions make them ideal for crops like tobacco, potatoes, coffee, cotton, and certain fruits and vegetables.

Water-soluble fertilizers are delivered through modern irrigation systems and must be highly soluble, rich in nutrients, free of impurities, and have a low salinity index. Potassium nitrate is a key nutrient here due to its balance of nitric nitrogen and chloride-free potassium, essential for plant nutrition in these systems.
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Potassium nitrate is crucial in foliar feeding to prevent and correct nutritional deficiencies and avoid stress. It aids in balancing fruit production and plant growth, especially in crops with physiological disorders.

16.2.3.1.3 Marketing and Customers
In 2024, we sold our specialty plant nutrients in approximately 100 countries and to more than 1,500 customers. No single customer individually accounted for at least 10% of sales in this segment during 2024. The 10 largest customers collectively accounted for approximately 25% of sales during that period. No supplier accounted for more than 10% of this business line's cost of sales.
The table below shows the geographical breakdown of our revenues:
Table 16-7. Geographical Breakdown of the Sales: Specialty plant nutrition
Revenues Breakdown202420232022
Chile12%12%11%
Central and South America (excluding Chile)12%8%11%
Europe17%14%17%
North America39%45%42%
Asia and Others21%21%20%

We distribute our specialty plant nutrition products globally through our network of commercial offices and distributors. In 2024, we saw continued growth in sales of differentiated fertilizers such as Ultrasoline® for enhanced root growth and optimal nitrogen metabolism, ProP® for improved phosphorus absorption, and Prohydric® which supports more efficient fertilization and water use.

We maintain inventory of our specialty plant nutrients at our commercial offices in key markets to facilitate prompt deliveries to customers. Sales are conducted through spot purchase orders or short-term contracts.

As part of our marketing strategy, we offer technical and agronomical assistance to clients. Our knowledge is based on extensive research and studies conducted by our agronomical teams in collaboration with producers worldwide. This expertise supports the development of specific formulas and hydroponic and fertigation nutritional plans, enabling us to provide informed advice.

By working closely with our customers, we identify the needs for new products and potential high-value markets. Our specialty plant nutrients are used on various crops, especially value-added ones, where they help customers increase yields and quality to achieve premium pricing.

Our customers are located in diverse regions, and as a result, we do not expect any seasonal or cyclical factors to significantly impact the sales of our specialty plant nutrients.

16.2.3.1.4 Competition

The primary factors influencing competition in the sale of specialty nutrients include product quality, logistics, agronomic service expertise, and pricing.

We consider ourselves the world's largest producer of potassium nitrate for agricultural purposes. Our potassium nitrate faces indirect competition from both specialty and commodity substitutes, which some customers may opt for depending on the soil type and crops involved.

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In 2024, our sales represented approximately 41% of the global agricultural potassium nitrate market by volume. In the 100% soluble potassium nitrate segment, our main competitor is Haifa Chemicals Ltd. ("Haifa") of Israel. We estimate that Haifa's sales accounted for around 22% of global agricultural potassium nitrate sales in 2024 (excluding sales by Chinese producers within the domestic Chinese market).

Kemapco, a Jordanian producer owned by Arab Potash, operates a production facility near the Port of Aqaba, Jordan. We estimate that Kemapco's sales comprised roughly 13% of global agricultural potassium nitrate sales in 2024.

ACF, another Chilean producer primarily focused on iodine production, has produced potassium nitrate from caliche ore since 2005. Additionally, several potassium nitrate manufacturers operate in China, with most of their production consumed domestically within China.

16.2.3.2 Potassium
In 2024, our potassium chloride and potassium sulfate revenues amounted to US$270.8 million, representing 6.0% of our total revenues and a 3.0% decrease compared to 2023, due to lower prices, partially offset by higher sales volumes during the year. The average price for 2024 was approximately 24.2% lower than the average prices in 2023. Our sales volumes in 2024 were approximately 28.0% higher than sales volumes reported during 2023.
The following table shows our sales volumes of and revenues from potassium chloride and potassium sulfate for 2024, 2023 and 2022:
Table 16-8. Potassium volumes and revenues, 2022 - 2024
Sales volumes
(Thousands of metric tons)
202420232022
Potassium chloride and potassium sulfate695.0543.1480.5
Total revenues
(In US$ millions)
270.8279.1437.2

16.2.3.2.1 Market

During the last decade, demand for potassium chloride and fertilizers in general has increased due to several factors, such as a growing world population, higher demand for protein-based diets, and less arable land. These factors contribute to fertilizer demand growth as efforts to maximize crop yields and continue to use resources more efficiently. It is estimated that demand in 2024 reached approximately 72 million metric tons, an increase from approximately 68 million tons during 2023, primarily due to lower prices and increased availability of potassium supply from Belarus and Russia.

Studies by the International Fertilizer Association indicate that cereals account for approximately 39% of global potassium demand, including maize (17%), rice (12%), and wheat (8%). Oil crops represent 25% of global consumption, with soybeans at 13% and oil palm at 9%. Other uses make up about 36%.

16.2.3.2.2 Products

We produce potassium chloride by extracting brines from the Salar de Atacama, which are rich in potassium and other salts. Potassium chloride is the most used and cost-effective potassium-based fertilizer for various crops. We offer potassium chloride in two grades: standard and compacted.

Potassium is one of the three essential macronutrients required for plant development. It is suitable for fertilizing crops that can tolerate relatively high levels of chloride and those grown under conditions with sufficient rainfall or irrigation to prevent chloride accumulation in the rooting systems.

The benefits of using potassium include:
Increased yield and quality
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Enhanced protein production
Improved photosynthesis
Intensified transport and storage of assimilates
Better water efficiency

Potassium chloride is also utilized as a raw material to produce potassium nitrate and other specialty nutrient granulated blends (NPK). Since 2009, our effective end product capacity has increased to over 2 million metric tons per year, providing us with greater flexibility and market coverage.


16.2.3.2.3 Marketing and Customers
In 2024, we sold potassium chloride and potassium sulfate to approximately 729 customers in 39 countries. No single customer individually accounted for at least 10% of this segment's sales in 2024. We estimate that the 10 largest customers together accounted for approximately 35% of sales during this period . No single supplier has a concentration of at least 10% of the cost of sales of this line of business. We make lease payments to Corfo which are associated with the sale of different products produced in the Salar de Atacama, including lithium carbonate, lithium hydroxide and potassium chloride. See Note 22.2 to our consolidated financial statements for the disclosure of lease payments made to Corfo for all periods presented.
The following table shows the geographical breakdown of our revenues:
Table 16-9. Geographical Breakdown of the Sales: Potassium
Revenues Breakdown202420232022
North America23%24%16%
Europe15%11%6%
Chile13%11%15%
Central and South America (excluding Chile)33%34%41%
Asia and Others16%20%22%

16.2.3.2.4 Competition

In 2024, it was estimated that we accounted for approximately 0.9% of the global sales of potassium chloride. Our main competitors are Nutrien, Uralkali, Belaruskali, and Mosaic. In 2024, Nutrien was estimated to account for approximately 15% of global sales, Uralkali for approximately 16%, Mosaic for approximately 8%, and Belaruskali for approximately 15%.
16.2.3.3 Other Products

SQM generates revenue from the sale of third-party fertilizers (both specialty and commodity). These fertilizers are traded globally in substantial volumes and are used either as raw materials for specialty mixes or to enhance our product portfolio. We have established capabilities in commercial management, supply, flexibility, and inventory management, enabling us to respond to the evolving fertilizer market and secure profits from these transactions.

Table 16-7. Geographical Breakdown of the Sales: Other products
Revenues Breakdown20242023
North America74%87%
Europe16%4%
Chile2%5%
Central and South America (excluding Chile)5%3%
Asia and Others3%1%
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17 ENVIRONMENTAL STUDIES, PERMITTING AND SOCIAL OR COMMUNITY IMPACT
The following section details the regulatory environment of the Site. It presents the applicable laws and regulations and lists the permits that will be needed to begin the mining operations. The environmental impact assessment process requires that data collection on many components and consultations to inform relevant stakeholders on site. The main results of this inventory and consultation process are also documented in this section. The design criteria for the water and mining waste infrastructure are also described. Finally, the general outline of the mine’s rehabilitation plan is presented to the extent of the information available now.

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17.1ENVIRONMENTAL STUDIES
The Law 19.300/1994 General Bases of the Environment (Law 19.300 or Environmental Law), its modification by Law 20.417/2010 and Supreme Decree N°40/2012 Environmental Impact Assessment Service regulations (D.S. N°40/2012 or RSEIA)) determines how projects that generate some type of environmental impact must be developed, operated, and closed. Regarding mining projects, the art. 3.i of the Environmental Law defines that mining project must be submitted to the Environmental Impact Assessment System (SEIA) before being developed.   
Florence Solar Evaporation Plant, submitted through EIA and approved by RCA 021/1999
New Pampa Blanca Salt Disposal Field, submitted through a DIA, and approved by RCA N° 232/2009 
Pampa Blanca Mine Area, submitted through an EIA and approved by RCA N° 278/2010 
Pampa Blanca Expansion, submitted through an EIA and approved by RCA N° 319/2013 
Only the first of these projects was executed, this was because in 2011 the Pampa Blanca operation began a temporary closure, which was extended until 2022.

Currently, the Environmental Impact Statement (EIS) "Modification of the Pampa Blanca Mining Facility through the Incorporation of a New Waste Salt Storage Area" is under environmental assessment, for which the first round of responses to the observations received by the services was delivered.

Additionally, the environmental assessment of the Pampa Blanca Seawater Pumping System project is being prepared, which includes the mine area and the seawater pumping system for future operation.

17.1.1 Baseline studies
Below is the information obtained for the environmental baseline of the EIS "Modification of the Pampa Blanca Mining Facility through the Incorporation of a New Salt Storage Area", and for the Environmental Impact Study under preparation:
Climate and Meteorology 
The location area is characterized by some climatic indices relevant to the component, with accumulated annual rainfall of 3 mm, average annual temperatures of approximately 7°C and an average wind speed of 3.1 m/s.
Air Quality 
Regarding the location of the Project in Sierra Gorda, it is indicated that there are no Atmospheric Decontamination Plans (PDA) or Atmospheric Prevention and Decontamination Plans (PPDA) in force.
The characterization of air quality was carried out with 4 monitoring stations. In order to have a representative characterization, the use of the most recent air quality information is privileged, limited to a maximum of 5 years prior to the year before the Project's entry. With this, the main results were the following:

There is no exceedance of the standard for respirable fine particulate matter (PM2.5) during the period under study, however, the Sierra Gorda station (Spence) presents for the daily standard of the pollutant values of the 98th percentile of the 24-hour concentration above the latency threshold.

For respirable particulate matter (PM10), for the daily standard, associated with the 98th percentile of the daily concentrations of the pollutant, all the Sierra Gorda (SCM), Sierra Gorda (Spence) and Sierra Gorda (Centinela) stations present values above the saturation value of the standard, while the Sierra Gorda (SQM) station presents values above the latency threshold. Regarding the annual standard of the pollutant, all the stations present values above the saturation value of the standard.

Regarding the primary quality standards of the gaseous pollutants carbon monoxide (CO), nitrogen dioxide (NO2) and sulfur dioxide (SO2), it is indicated that the statistics obtained represent a maximum of 40.5% of their respective standards, this situation being observed in the hourly standard of NO2 at the Sierra Gorda (SQM) station. 

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Hydrology 
The statistical analysis of precipitation leads to the conclusion that the study area has practically no precipitation, with an average annual value of no more than 3 mm. Because of this, possible infiltration into groundwater is dismissed.  
Based on the hydrographic and hydrologic background, it can be concluded that in the project site area, that is, in the mine areas, in the Pampa Blanca industrial facilities, there are no significant permanent surface runoffs that could be affected. Average evaporation in the study area is 10.1 mm/day, with peaks between October and March. The monthly distribution of evaporation is consistent with the behavior of existing stations in the northern part of the country.  
Actual evaporation in the area is restricted by the lack of available water to be evaporated. As a result, a large part of the rainfall in the area is consumed by evaporation processes. 
Hydrogeology 
Linear Works (Linear Sector A, B and C)  
Based on the geological and hydrogeological background, it can be concluded that in the area where the linear works are located, there are at least seven sectors where the hydrogeological characteristics, inferred from the surface information, would favor the presence of groundwater. However, there are no records of recognized aquifers in this sector except for the southwest sector of the industrial areas and the power line near these facilities, where the Sierra Gorda aquifer is located. 
The Sierra Gorda aquifer, in this sector, has superficial layers of very low permeability. These layers would be approximately 30 m thick and would be made up of fine clastic material such as silts and clays. In this sector the depth of the water table varies between 8 and 39 m.
Areal Works (Mine and Industrial Sector) 
Based on the geological and hydrogeological background presented, it can be concluded that there are no aquifers of interest in the area where the areal works are located, apart from the industrial zone located to the south. It was determined that in the site area the rock, which has a very low permeability, practically outcrops on the surface and that in the areas where there is fill, it has small thicknesses (3 m). This implies that there is no potential to host an aquifer.  
The industrial sector located in the southern part of the study area is partially located within the limits of the Sierra Gorda aquifer. However, the Sierra Gorda aquifer, in front of this industrial area, has superficial layers of very low permeability. These layers correspond to Hydrogeological Units 4 and 5, which are approximately 30 m thick. In this sector, the depth of the water table varies between 8 and 39. 
 
Soils 
Regarding the main findings of the soil resources present in the area of influence, highly saline and fragile soils are observed, which correspond to soils where the establishment of vegetation is not viable, therefore they are very susceptible to erosion, either by the action of water or wind agents, implying that they are also erodible soils, which present limited pedogenic development in depth, which shows a low capacity to sustain biodiversity in the soils present in the Project area.

Regarding the Biodiversity Sustaining Capacity (BSC) in the Area of Influence, it presents Very Low BSC. This is due to the conditions of the origin of the parent material, the aridic humidity regime characteristic of the region and the high saline and sodium concentration of the soil. Currently, there are restrictive conditions in the capacity to sustain biodiversity, which is consistent with the absence of vegetation cover seen throughout the area.

Flora and vegetation 
-Vegetation
The Area of Influence (AI) defined for the Project covers a total area of 12,248.22 ha and 99.99% of the AI corresponds to areas without vegetation and industrial zones. This is clearly consistent with an Absolute Desert condition. On the other hand, areas of scarce vegetation were detected that cover an area of 0.60 ha (0.005%) where the only recorded species corresponds to Nolana clivicola.

According to the above and under the sampling effort of 1,448 sampling points, within the AI there are no formations regulated by Chilean legislation.

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- Flora
Within the AI, the presence of only one taxa identified as Nolana clivicola was detected, an endemic shrub, distributed only in the northern zone of Chile, in the Antofagasta and Atacama Regions. This taxa is not registered under any conservation category and represents 0.02% of the national vascular flora. It is worth mentioning that the record was of isolated individuals in only two sampling points.

Terrestrial fauna 
In the EIA study area, three [3] environments for wildlife were identified. Among these, the environment with the largest surface area corresponded to the interior desert, covering 90.47% of the total study area, while the coastal desert environments of Tocopilla and the coastal border comprised 8.18% and 1.35%, respectively.
During the seven campaigns for characterizing Wild Animals, a sampling effort of 4,197 points was obtained. In these, 37 species of terrestrial fauna were identified, of which 35 correspond to native species and two [2] are of exotic origin. Of the 35 native species, 3 are endemic, a total of 3 reptiles, 28 birds and 4 native mammals were recorded.

The environment that presented the greatest richness corresponded to the coastal border, with a total of 24 species, and with a predominance of the bird class (23 species recorded). In the interior desert environment, 13 species were recorded, with the coastal desert environment of Tocopilla being where the lowest richness was observed, with 9 species detected.
Of the total number of native species, 15 species classified in the Regulations for the Classification of Wild Species of Chile were recorded, and 20 species presented some singularity.

Regarding the classified species, six [6] are in the category of Least Concern (LC), one [1] species in the Data Deficient (DD) category, six [6] Near Threatened (NT), one [1] Vulnerable (VU) and one [1] in the Endangered (EN) category. Among the singular species, the bird class stands out, which constitutes 53.57% of species considered as singular fauna.

Regarding abundance and density, the reptile with the greatest abundance was the Atacama runner (M. atacamensis), presenting its highest average density in the coastal environment. Similarly, in this same environment, a great abundance of the garuma gull (L. modestus) was observed through the censuses carried out.

In the coastal desert environment of Tocopilla, the lesser sleepyhead (M. maculirostris) had the highest average density, while, for the mammal class, the olive-bellied mouse (A. olivaceo) recorded the highest density.

In the case of macromammals, the culpeo fox (L. culpaeus) was identified by camera trap in the coastal desert environments of Tocopilla and the interior desert, while indirect records (footprints, feces and bone remains) of fox were obtained in both environments.

No species of the order Chiroptera were recorded, nor were there specimens or suitable conditions for the presence of amphibians. Regarding daytime air traffic, 23 species were recorded in the surveyed sector, of which 12 presented some singularity. The most frequent species was the red-headed vulture (C. aura), and the rest of the species were concentrated exclusively in the coastal environment.

Two particularly sensitive species were identified using the avifauna sensitivity index (ISA): the garuma gull (L. modestus) and the little tern (S. lorata). It should be noted that all the species recorded (with the exception of the red-headed vulture) are characterized by mainly traveling to the sea in search of food. There were no records of birds with the nocturnal air transit methodology.

Regarding the prospecting of nesting birds, three [3] species were identified: the garuma gull (L. modestus), the little tern (O. gracilis) and the little tern (S. lorata), in addition to a record of a tern carcass not identified at the species level.

By actively searching for nests, the presence of active nests of the Little Tern (S. lorata) was found near the coastal edge of Mejillones, coinciding with records of colonies in the literature. In addition, inactive nesting sites for the Garuma Gull (L. modestus) were identified towards the interior of the desert. Through different methodologies (transects and camera traps) their activity was ruled out during two reproductive periods.

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Finally, with respect to the sea swallows, no suitable surfaces for nesting of these species (salt crusts and/or cavities) were found near the study area of the Project, only three [3] Procellariiformes carcasses were recorded in the Project area, which would be associated with falls in sectors with facilities and associated lighting. Diversity indices and species accumulation curves indicate a medium diversity in the coastal edge environment and a low diversity in the coastal desert of Tocopilla, together with the interior desert environment, which can be explained by the low availability of water and food in desert environments. Species accumulation curves indicate a high sampling coverage for all environments.
 
Human Environment 
The area of influence of the human component is determined by the administrative boundaries of the towns of El Oasis and Baquedano, where the human groups closest to the Project live.
In the Sierra Gorda commune, mining is the main economic driver, since 71.06% of its inhabitants work in this sector. This industry is responsible for significant demographic fluctuations due to the floating population and migration linked to employment opportunities. In relation to the Area of Influence, the El Oasis hamlet acts as a temporary stop for vehicles, especially public transport and freight, that travel along Route 5. This circulation has led to the development of a small community established next to a service station, serving as a rest point.

With respect to the village of Baquedano, the main activities revolve around mining support services, following a trend similar to that of the communal context. In El Oasis, the service station-related trade prevails, although there are no strong ties to the territory or deep-rooted cultural practices due to the itinerant nature of the population and its function as an access route for the mining industry in the region. Similarly, the village of Baquedano is characterized by retail businesses, as well as lodging and restaurant services. Additionally, the local council is an important provider of employment, both in professional and technical and trade positions.

It has been identified that in the village of El Oasis, apart from having a service station, there are no education, health or security facilities nearby, the closest being located about 26 km to the southwest in Baquedano or about 45 km to the northeast in Sierra Gorda. Regarding the access roads in El Oasis, routes 5 and 25 stand out, which join near the service station and facilitate the connection with the town. Additionally, in Baquedano, Route 5 North connects with Salvador Allende Avenue, the main road in the area. These roads, paved and suitable for heavy traffic, link the area of influence and other local towns with the cities of Antofagasta to the west and Calama to the east.

Regarding the possible effects of climate change, the risks of drought in mining operations and the increase in population morbidity are not linked to the Project activities. The threats mentioned in the ARClim platform related to the increase in temperatures and precipitation are not expected to generate significant impacts on the installation of the Project in the area during its three years of operation.

Thus, it is concluded that the Area of Influence and in particular the communities of the human groups that inhabit the hamlet of El Oasis and the village of Baquedano, would not experience significant changes in their life systems and customs due to Climate Change or the actions carried out by the Project.

Cultural Heritage 
Terrestrial archaeology 
The results of the archaeological survey for the archaeological baseline of the project yielded a total of 1,109 archaeological findings during the survey, plus 9 findings identified in the review of bibliographical background, so that in total the area presents 1,118 findings. Among the findings, those of carving events, concentrations and isolated lithics findings predominate considerably, while among the historical findings there are cart tracks and dispersion of historical garbage associated with nearby saltpeter offices.

According to the above, it is concluded that the area of influence of the project had occupations in pre-Hispanic times oriented towards obtaining raw materials for the elaboration of lithics tools, while in historical times it was a transit area from the saltpeter offices to the production sectors.

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It should be noted that during the survey, a significant number of lithics events associated with thermal fractures were observed. It is important to mention that not everything observed is truly artificial, since there are places where there are good raw materials, but they are naturally fractured. The most indicative of this is when pseudo-flakes are found gathered in a very limited space, most of them of a primary nature, with ample capacity for reassembly, without missing pieces that could have been useful to the presumed carver and without the presence of flakes with any retouching. Less of any hammer. In short, there is no reduction chain in the place, everything is very limited and nothing is missing.

For the large number of lithics sites, it is worth highlighting that these extensive desert pampas, typical of the Intermediate Depression of the Atacama Desert, have been conceptualized by regional archaeology as a marginal or internodal space, whose vestiges of human activities refer mainly to the access of coastal populations to its lithics quarries and minerals (Blanco et al 2010, Blanco 2015, Gallardo and Ballester 2010), or to the caravan transits that connected the populations of the highlands with the coastal populations since the Middle Formative (Berenguer 2004, Berenguer and Pimentel 2006, Blanco et al 2010, Blanco 2012).
Paleontology 
In the Project's area of influence, it was possible to corroborate the presence of paleontological objects (fossils) in the geological unit called Marine Deposits (low succession). In addition to these findings, in a ravine near the Pampa Blanca sector, limestone rocks were identified, transported from the Rencoret Strata unit, a unit that has numerous paleontological antecedents. These transported limestones were found redeposited and currently contained in the Modern Alluvial and Colluvial Deposits unit.
Based on the geological and paleontological antecedents, added to the observations and findings made in the field, a Medium to High paleontological potential and a Fossiliferous paleontological category for the Marine Deposits were determined. In turn, for the alluvial and colluvial deposits, a medium to low paleontological potential and a Susceptible category were determined, with the exception of the aforementioned ravine, where blocks from the Rencoret Strata occur. For this exclusive sector, a medium to high paleontological potential was determined, and a corresponding Fossiliferous category, following the current CMN criteria (2016). In the case of regoliths, in addition to the units called La Negra Formation, Quebrada Mala Formation, Cerro Cortina Strata, Algorta Strata, Oligocene-Lower Lower Miocene alluvial deposits, Baquedano Gravels, Lower Miocene-Lower Upper Miocene alluvial deposits, Ancient alluvial and colluvial deposits, Modern alluvial and colluvial deposits, and Holocene alluvial and lagoonal deposits, a Low to Medium potential and a Susceptible paleontological category were determined for all of them.

Finally, the intrusive units Oficina Ercilla Batholith, Mejillones Gabro, Cerro Fortuna Dioritoides, Naguayán Plutonic Complex, Los Dones Plutonic Complex, Hypabyssal Intrusives; Sierra Miranda-Cerro Camaleón Rhyolites volcanic unit; and anthropic unit Anthropic deposits, were assigned a Low to Null paleontological potential and a Sterile paleontological category, due to their genesis.

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17.1.2 Environmental Impact Study
Regarding the Pampa Blanca Expansion, the EIA submitted by the company and approved by RCA N°319/2013 analyzed the project activities and their potential environmental impacts. The following table shows the environmental components that could be directly or indirectly affected during the different phases of the project accordingly with the information submitted in the environmental assessment process.
Table 17-1. Environmental impacts of the Pampa Blanca project and committed measures
Phase in which it occurs Environmental component Impact 
ConstructionPhysical environmentHealth risk to the population from particulate matter emissions
Risk to the health of the population due to noise emissions
Risk of changes in groundwater quality due to eventual spills in industrial area N° 2
Biotic environmentPossible alteration in abundance of Sterna lorata (Little Tern) due to loss of habitat quality
Possible alteration in the abundance of the Larus modestus (Gaviota garuma) population due to loss of habitat quality.
Possible alteration in the abundance of the population of Haematopus palliatus (Pilpilén) due to loss of habitat quality.
Possible alteration in the abundance of the Microlophus quadrivitattus (Four-banded Runner) population, due to loss of habitat quality.
Marine environmentPossible alteration of the physical-chemical quality of the seawater column due to the construction of the seawater intake system.
Alteration of the abundance of biological resources and species as a result of seawater adduction.
Historical, archaeological, and cultural aspectsHeritage impact due to areal works
Cultural heritage impact due to linear works
PaleontologyAlteration of paleontological heritage due to construction of linear works in linear sector A
LandscapeAlteration of the landscape value due to the construction and habilitation of industrial areas
Alteration of the landscape value due to construction of aqueduct and electric transmission line in the linear sector A
Alteration of landscape value due to construction of power transmission line in linear sector B
Alteration of landscape value due to construction of power transmission line in linear sector C
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OperationPhysical environmentHealth risk to the population from particulate matter emissions
Risk to the health of the population due to noise emissions
LandscapeAlteration of landscape value due to caliche extraction and stockpile operation
HydrologyRisk of changes in groundwater quality due to infiltration of solutions in industrial area N°2
Biotic environmentAlteration in the abundance and distribution of bird fauna populations due to flight path barriers.
Marine environmentDecrease in planktonic communities due to the operation of the seawater adduction system.
Historical, archaeological, and cultural aspectsAlteration of the patrimony by exploitation of mining areas
For those significant environmental impacts defined in the RCA, management measures were designed to mitigate, repair, and compensate the relevant affected elements. See Table 17-2.

17.2OPERATING AND POST CLOSURE REQUIREMENTS AND PLANS

17.2.2 Waste Disposal Requirements and Plans 
Two types of waste are generated during mining operations. Mineral and non-mineral wastes.
1. Mineral waste 
It should be noted that the Site has been in the reopening phase since December 23, 2021. Since then, repair, maintenance, replacement and/or renovation activities have been carried out on the facilities and equipment that were temporarily paralyzed. suit them for your operation. Additionally, and as indicated by SERNAGEOMIN in RE 802/2019 that approves the Temporary Closure Plan of the site, it establishes in its first resolution, literal b.7 "Facilities that temporarily paralyze their operations", that the possibility remains active to extract salts rich in nitrate collected at the site, for processing at other sites. In the same way, the removal of discard salts is carried out, collecting them in sectors enabled for that.
Mining residues come from material from nitrate salt-rich evaporation pool ponds and leaching piles (caliche). Mineral waste management is as indicated in the closure plan section.
2. Non-mineral waste.  

Two types of industrial waste are generated:

Mining waste corresponding to discarded salts from evaporation ponds which are deposited in area authorized by Sernageomin
non-hazardous industrial waste such as liner, pipes, scrap metal, among others, and hazardous waste such as oil and batteries which are deposited in an authorized location.
17.2.1 Monitoring and Management Plan Established in the Environmental Authorization
The last project presented through an Environmental Impact Assessment system called “Pampa Blanca Expansion", approved through RCA 319/2013, was submitted through an Environmental Impact Assessment (EIA) given the generation of significant impacts in the habitat and population of the specie Microlophus quadritattus (four banded runner) and for the intervention of 13,893 heritage elements. 
The following table shows the measures committed to address the significant and not significant impacts of the project.
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Table 17-2. Mitigation, Remediation and Compensation Plan 
Measure type 
Phase
Environmental component
Measures
MitigationConstructionBiotic environmentInstallation of appropriate signage to identify the presence of Microlophus quadrivattus. 
Implementation of a rescue and relocation plan for Microlophus quadrivattus, to avoid affecting the population present in the area.
Construction, operationHistorical, archaeological, and cultural aspectsEstablishment of two exclusion areas representative of the historical and pre-Hispanic occupations observed during the project baseline. 
Perimeter topographic and photographic survey and context description of the elements incorporated in the exclusion areas. 
Field definition of the exclusion areas. The polygons will be established by topographers advised by the archeology team, to install a protective perimeter fence. The fenced area will have a buffer of at least 50 meters for the area located in the mining zone and 25 meters for the area located in the industrial zone. 
Signs will be posted in the polygons defined for the two exclusion areas. 
Biannual monitoring of the conservation status of the sites registered in the exclusion areas.
Compensation-Historical, archaeological, and cultural aspectsExhibition of elements of the history of saltpeter and Pampan identity reflected in daily life. 
Implementation of conservation measures while the recovered materials are being processed for their destination, as well as during transport. 
Elaboration of a public cadaster (documentary information system) where the archaeological information is exhibited, along with photos and/or illustrations of the saltpeter cycle. It could be exhibited from the SQM portal, or through the development of another web portal. 
Compilation and exhibition of the narrative associated with the saltpeter cycle (stories and novels), to rescue the oral tradition and its use as documentary material. 
A virtual tool will be developed, based on the use of Geographic Information Systems (GIS) that will make it possible to disseminate in a clear and simple way how the space was used by the pre-Hispanic populations. As in the case of the saltpeter cycle, it could be exhibited from the SQM portal, or through the development of another web portal. The platform will include information on the legal protection status of archaeological heritage in general, and the appropriate measures and behavior when making archaeological finds.
Other measuresConstructionAir qualityStabilization of the main access road to the industrial zone (Sectors 1 and 2), including access from Route 5. The owner must keep available, at the request of the authority, the maintenance records of the roads to which bischofite stabilization will be applied, indicating at least the date, section, and signature of the person in charge.  
Wetting of unpaved secondary roads, with 75% abatement of emissions. Monthly efficiency measurements will be taken.  
Moistening of areas where earthworks are carried out. 
Preparation and compaction of soil and unpaved areas where vehicles and machinery circulate. 
Transport of material with covered loads. 
Restriction of vehicle speeds. 
Requiring all contractors to carry out the required inspections and maintenance of all machinery and equipment, especially those elements intended to control noise emissions (mufflers). 
Restriction on the use of horns. 
Use of machinery and tools in a good state of maintenance, according to the manufacturer's specifications.
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Biotic environmentIdentification of possible nesting sites of Sterna lorata (Little Tern), Haematopus palliatus (Pilpilén) and Larus modestus ( Garuma Gull). If nesting sites are identified, signs will be installed to identify their presence to avoid affecting them, and any activity will be prohibited during the nesting season. 
There will be combs on the signage, specially designed to prevent birds from nesting, to avoid the nesting of predatory birds of prey that prey on the species. 
The activities of the construction phase that will be developed in the sectors of greatest risk (Ex Oficina Ercilla and Sierra Valenzuela sectors), will be carried out outside the reproductive period (September-February) of Larus Modestus. 
Development of a micro-routing, with an accredited professional, to carry out an inspection and survey of the work areas for the linear works of Section A, to release sectors that do not present evidence of nesting of Garuma Gull. 
If the presence of Larus modestus pairs, eggs, chicks and/or fledglings is detected, access and any activity related to the construction of the project in these areas will be prohibited while there is activity of this species. 
Monitoring will be carried out in the sectors at greatest risk (Ex Oficina Ercilla and Sierra Valenzuela) and will consist of three field campaigns that will be carried out during the months of greatest reproductive activity (November, December, and January) and a report will be generated for each campaign that will be submitted to the authorities, detailing the activities carried out, the results obtained, and the pertinent recommendations. Based on these reports, the need to maintain, reduce, modify, or take new corrective or mitigation actions can be evaluated. This monitoring will be carried out for a period of three reproductive periods of the species. 
The areas of intervention and machinery traffic will be delimited to restrict movements to sectors that do not compromise the habitat of the Lesser Tern, Lesser Black-backed Tern, and Lesser Black-backed Gull. 
The circulation of pedestrians, vehicles or machinery will be prohibited in the nesting areas of the Little Tern and Pilpilén located in the sectors adjacent to the limits of the construction of the project. 
Inductive talks will be given to contractors on the environmental value of the Little Tern, Garuma Gull, and Pilpilén, and the precautions to be taken during construction work. 
The implementation of the proposed measures will be coordinated with the “Fundación para la Sustentabilidad del Gaviotín Chico”. 
Installation of flight diverters in areas of the TL. 
Installation of "SuperbirdXPellerPro" bird and fauna repelling devices in facilities that could form bodies of water. 
Perimeter closure of the industrial sector where the seawater ponds will be located to prevent the entry of fauna. 
Application of wildlife treatment procedures in the event of a wildlife sighting and/or presence. 
The concessionaire agrees to participate in public-private partnerships that allow for the conservation and protection of the Larus modestus species.
Human environmentHiring local and communal labor will be favored, with special emphasis on the communes of Sierra Gorda and Mejillones. 
Talks and training will be given to the people who will work on the project to encourage and promote responsible behavior in the community living near the project. 
For the acquisition of supplies and materials, and given equal conditions, preference will be given to local companies, followed by regional companies, and finally national and foreign companies. 
Food services and personnel transportation will be contracted preferably from local and community suppliers.
PaleontologyPaleontological monitoring during the installation of the aqueduct, to minimize impacts on sectors with heritage value and/or recover fossil pieces that may eventually appear during work involving intervention of the stratum. 
If fossils are recovered, they will be sent to an institution that will ensure their conservation and enhancement.
LandscapeThe appropriate location of the works, and the minimization of the levels of disturbance and repetition of basic elements will be favored.
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OperationPhysical environmentStabilization of the main access road to the industrial zone (Sectors 1 and 2), including access from Route 5. The owner must keep available, at the request of the authority, the maintenance records of the roads to which bischofite stabilization will be applied, indicating at least the date, section, and signature of the person in charge. 
Wetting of unpaved secondary roads, with 75% abatement of emissions. Annual efficiency measurements will be taken. 
Commitment to caliche extraction rate in sector 4 of 18.65 million tons/year. 
Moistening of areas where earthworks are carried out. 
Preparation and compaction of soil and unpaved areas where vehicles and machinery circulate. 
Transport of material with covered loads. 
Registration of vehicle speeds. 
Requiring all contractors to carry out the required inspections and maintenance of all machinery and equipment, especially those elements intended to control noise emissions (silencers). 
Restriction on the use of horns 
Use of machinery and tools in a good state of maintenance, according to the manufacturer's specifications. 
The licensee will keep the current calibration certificates of the machines used for melting HDPE membranes available for the state environmental agencies. 
A leach pad construction report will be submitted to the Regional Directorate of the DGA, including photographs of each stage and certification of the binder joints. In addition, the start date of this activity will be informed in advance. 
Any changes in the location of the solar evaporation ponds will be reported to the relevant agencies. 
The General Water Directorate will be informed in advance about the supply of water from third parties (source, catchment point, sectorial and environmental authorizations that may apply). 
Background information will be submitted to the Municipal Works Department of Mejillones Commune on the handling of excess material generated from excavations carried out in the Commune. 
A final construction report of the evaporation ponds, seawater ponds, industrial water ponds and neutralization ponds will be sent to the Regional Directorate of the DGA, which must include photographs of each stage and the appropriate certifications. 
Companies supplying aggregates and borrow materials must have all the environmental authorizations. This information must be submitted to the Superintendency of the Environment prior to the purchase of these inputs.
Biotic environmentInstallation on the guard cable of spiral and firefly type flight diverters, whose material allows them to glow for up to 10 hours during the night. 
In the case of Sterna lorata, the deterrents will be placed between vertices 1 to 19, in the area between the coast and route 1. 
In the case of Larus modestus, the deterrents will be placed in the nearby nesting areas or routes, between vertices 94 to 147. 
In the highest risk sectors (Ex Oficina Ercilla and Sierra Valenzuela sectors), anti-equalization and anti-electrocution elements will be placed on the power lines, as well as the use of supports with anti-nesting systems or vertical hanging insulators. 
A wildlife management procedure will be implemented. It should be noted that the owner is expected to assume the costs of rescue and rehabilitation. 
A final monitoring report will be submitted at the end of the maritime works emplacement activities during the construction phase. The monitoring will be carried out with three stations adjacent to the works and one control station, and the parameters total suspended solids, dissolved oxygen, and turbidity in the marine environment will be measured. This report will be submitted to the Maritime Governor's Office and the Superintendency of the Environment.
Human environmentHiring local and communal labor will be favored, with special emphasis on the communes of Sierra Gorda and Mejillones. 
Talks and training will be given to the people who will work on the project to encourage and promote responsible behavior in the community living near the project. 
For the acquisition of supplies and materials, and all other things being equal, preference will be given to local companies, followed by regional companies, and finally national and foreign companies. 
Food services and personnel transportation will be contracted preferably from local and community suppliers.
Source: own elaboration 
Additionally, the project committed some monitoring activities to follow up the different components during the construction and operation of the project.
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Table 17-3. Environmental Monitoring Plan 
PhaseEnvironmental ComponentMeasureDetails
ConstructionArchaeologyExclusion area N°2 monitoringMonitoring will be done through a visual inspection of the perimeter closures, signage, and control sectors. The frequency of monitoring will be every six months, prior to the construction phase and until abandonment. 
In addition, during the construction phase and on the sites that will be intervened, reports will be sent to the National Monuments Council through the authorizations for the intervention or release of work areas.
Biotic environmentMicrolophus quadrivitattus monitoringMonitoring of individuals and areas used for the relocation of this species will be carried out. Monitoring will be carried out 15 days after capture, and then every 3 months in the first year and every 6 months thereafter, until 2 years of monitoring are completed.
OperationArchaeologyExclusion areas N°1 and N°2 monitoringMonitoring will be done through a visual inspection of the perimeter closures, signage, and control sectors. The frequency of monitoring will be every six months, prior to the exploitation and intervention phase of mine sectors 3 and 4, until abandonment.
Other construction measuresBiotic environmentIdentification and georeferencing of Sterna lorata nesting sitesRecording will be carried out in a 500-meter strip along the axis of the route of the linear works located in the potential nesting area of the species on the Mejillones coast. The activity will be carried out bimonthly during the reproductive phase (July to February).
Identification and georeferencing of Larus modestus nesting sitesRecording will be carried out in a 500-meter strip along the route of the linear works located in the potential nesting area of the species, in the section that crosses the coastal mountain range and part of the inland desert of the Antofagasta Region. The activity will be carried out every two months during the reproductive phase (November to February).
Identification and georeferencing of Haematopus palliatus nesting sitesRecording will be carried out in a 500-meter strip along the route of the linear works located in the potential nesting area of the species, along the coastal border around the Mejillones cliffs. The activity will be carried out every two months during the reproductive phase (October to February).
Larus modestus monitoring in Ex Oficina Ercilla and Sierra Valenzuela sectors.Monitoring will be carried out in the sectors at greatest risk (Ex Oficina Ercilla and Sierra Valenzuela) and will consist of three field campaigns, which will be carried out in the middle of the months of greatest reproductive activity (November, December and January), and a report will be generated for each campaign, which will be submitted to the authorities and will detail the activities carried out, the results obtained and the pertinent recommendations. 
The monitoring will be carried out for a period of three reproductive periods of the species.
Physical EnvironmentAir quality monitoringMeasurements of air quality levels (MP10) will be made in the town of Baquedano by means of a discrete type Monitoring Station with a Hi Vol monitor. The monitor will be in operation prior to the construction and operation phase of the mine areas, to improve the knowledge of the baseline situation, and then continue with a 5-year period, which covers the construction and 3 years of operation.
Assessment of the contribution to air qualityAn evaluation of the air quality contribution of this Project will be carried out annually, considering the variation in the generation of emissions, according to the update of the Mining Plan.
Marine environmentDissolved oxygen monitoringDissolved oxygen monitoring will be conducted during the excavation phase for the marine works.
Marine water quality monitoringThe following variables will be monitored: suspended material and turbidity. In case the values of total suspended solids exceed 400 mg/L, maritime works will be suspended until it returns to its previous conditions.
PaleontologyPaleontological resource monitoringPaleontological monitoring will be carried out by a professional paleontologist, geologist, or biologist with experience in paleontology, and a report will be submitted to the National Monuments Council. The monitoring will be carried out once during the construction phase.
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Other construction measuresBiotic environmentIdentification and georeferencing of Sterna lorata nesting sitesRecording will be carried out in a 500-meter strip along the axis of the route of the linear works located in the potential nesting area of the species on the Mejillones coast. The activity will be carried out bimonthly during the reproductive phase (July to February).
Identification and georeferencing of Larus modestus nesting sitesRecording will be carried out in a 500-meter strip along the route of the linear works located in the potential nesting area of the species, in the section that crosses the coastal mountain range and part of the inland desert of the Antofagasta Region. The activity will be carried out every two months during the reproductive phase (November to February).
Identification and georeferencing of Haematopus palliatus nesting sitesRecording will be carried out in a 500-meter strip along the route of the linear works located in the potential nesting area of the species, along the coastal border around the Mejillones cliffs. The activity will be carried out every two months during the reproductive phase (October to February).
Larus modestus monitoring in Ex Oficina Ercilla and Sierra Valenzuela sectors.Monitoring will be carried out in the sectors at greatest risk (Ex Oficina Ercilla and Sierra Valenzuela) and will consist of three field campaigns, which will be carried out in the middle of the months of greatest reproductive activity (November, December and January), and a report will be generated for each campaign, which will be submitted to the authorities and will detail the activities carried out, the results obtained and the pertinent recommendations. 
The monitoring will be carried out for a period of three reproductive periods of the species.
Physical EnvironmentAir quality monitoringMeasurements of air quality levels (MP10) will be made in the town of Baquedano by means of a discrete type Monitoring Station with a Hi Vol monitor. The monitor will be in operation prior to the construction and operation phase of the mine areas, to improve the knowledge of the baseline situation, and then continue with a 5-year period, which covers the construction and 3 years of operation.
Assessment of the contribution to air qualityAn evaluation of the air quality contribution of this Project will be carried out annually, considering the variation in the generation of emissions, according to the update of the Mining Plan.
Marine environmentDissolved oxygen monitoringDissolved oxygen monitoring will be conducted during the excavation phase for the marine works.
Marine water quality monitoringThe following variables will be monitored: suspended material and turbidity. In case the values of total suspended solids exceed 400 mg/L, maritime works will be suspended until it returns to its previous conditions.
PaleontologyPaleontological resource monitoringPaleontological monitoring will be carried out by a professional paleontologist, geologist, or biologist with experience in paleontology, and a report will be submitted to the National Monuments Council. The monitoring will be carried out once during the construction phase.
Source: own elaboration 

Requirements and plans for water management during operations and after closure. 

17.3ENVIRONMENTAL AND SECTORIAL PERMITS STATUS
The Pampa Blanca mine, as indicated in Section 1.1 to the Environmental Impact Assessment System (SEIA) a total of 4 times.
Florence Solar Evaporation Plant, (EIA, 1999)
New Pampa Blanca Salt Disposal Field (DIA, 2009) 
Pampa Blanca Mine Zone (EIA, 2010) 
Pampa Blanca Expansion (EIA, 2013) 
Currently, the Environmental Impact Statement (EIS) "Modification of the Pampa Blanca Mining Facility through the Incorporation of a New Waste Salt Storage Area" is under environmental assessment, for which the first round of responses to the observations received by the services was delivered. Additionally, the environmental assessment of the Pampa Blanca Seawater Pumping System project is being prepared, which includes the mine area and the seawater pumping system for future operation.
All these studies were approved by the corresponding environmental authority, however, only the EIA Florencia Solar Evaporation Plant was executed.  
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According to current legislation, the General Environmental Law and Supreme Decree 132 of 2002, which approves the Mining Safety Regulations, there are a series of permits required to operate a mining project. These are the sectorial permits, which can be filed with SERNAGEOMIN, or another service with competence of sectoral environmental permits.
In the following table are mentioned the sectorial permits defined in the RCA 021/1999, as is the only project that have been executed.
Table 17-4 Sectorial Permits defined the RCA "Florencia Solar Evaporation Plant".

Table 17-4. Sectorial Environmental Permits.
ProjectRCAPermits N°Permit Name
Solar evaporation plant Florence021/199988Permission to establish a reserve of mining waste and tailings dumps.

These permits are found in the old regulations of the environmental impact assessment system, repealed by decree 40 of 2013. In addition, Pampa Blanca has an Exploitation Method and benefit authorized by Sernageomin through:
Resolution Ex 1499/2000. Modification of the Exploitation of Calichera Quarries.
On the other hand, the Exempt Resolutions issued by the National Geology and Mining Service (SERNAGEOMIN) associated with the site correspond to:
Exempt Resolution N°821/2009 authorizing Pampa Blanca Closure Plan.
Exempt Resolution N°368/2010 authorizing the Temporary Closure of Pampa Blanca.
Exempt Resolution N°1346/2012 authorizing the extension of the Temporary Closure, Pampa Blanca Closure Plan.
Exempt Resolution N°1424/2015 that approves the project (Valorization) of the Closure Plan of the Pampa Blanca Mining Plant.
Exempt Resolution N°2873/2017 that favorably qualifies the guarantee accumulated to 2017 of the valorization projects for the Closure Plan of the Mine "Pampa Blanca".
Exempt Resolution N°802/2019 that approves the project Temporary Closure Plan for the Pampa Blanca Mine.
Exempt Resolution N°1304/2020 that approves the Expansion of the Temporary Closure Plan for the Pampa Blanca Mine.

Exempt Resolution N°0292/2023 that approves of the Closure, Pampa Blanca Closure Plan.

Exempt Resolution N°0224/2024 Authorization for waste disposal -Storage of waste as a waste dump”
17.4SOCIAL AND COMMUNITY

17.4.1 Plans, Negotiations or Agreements with Individuals or Local Groups 
The company has established agreements with indigenous and non-indigenous organizations on different aspects that derive both from previous commitments and from programs associated with corporate policies on community relations, for example:
Antofagasta Educa Program through the Entrepenuer Foundation, in the schools of Estación Baquedano G-130 and Complejo Educativo Caracoles.

Working with Chacabuco Corporation on issues of heritage significance

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17.4.2 Local hiring commitments 
Communication has been established with the OMIL of the Sierra Gorda Municipality, where job vacancies are sent via email on a weekly basis.
17.4.3 Social Risk Matrix 
The social risk matrix classifies the various impacts that SQM's activities could have on its operations, reputation, regulatory compliance and commitment to sustainability. In this way, the impacts are classified by probability of occurrence, from improbable to almost certain, and their consequences, from negligible to very high.
Based on the results of this classification, an analysis can be made to distinguish between the locations analyzed, the associated risk level (low, medium, significant or extreme), priority (low, medium or high) and the operation to which it is associated.

This allows a clear focus on the sectors and areas that could be affected and, based on the results provided by the risk matrix, to monitor and establish programs to identify threats and opportunities for improvement.

Although it is not possible to provide detailed information on the matrix due to the company's confidential analysis, it can be noted that no risks classified as extreme have been identified.
17.5MINE CLOSURE

17.5.1 Closure, Remediation, and Reclamation Plans  
In accordance with the provisions of Law No. 20,551, Res. Ex. No. 0040/2020 and Res. Ex. No. 1092/2020, the Update of the Pampa Blanca Slaughter Closure Plan, approved by Res. Ex. 292/2023.
During the abandonment stage of the Project, the measures established in the Update of the Closure Plan "Faena Minera Pampa Blanca" approved by the National Geology and Mining Service (SNGM), through Resolution N° 292/2023, will be complied with.
Among the measures to be implemented are the removal of metal structures, equipment, materials, panels and electrical systems, de-energization of facilities, closure of accesses and installation of signage. The activities related to the cessation of operation of the site will be carried out in full compliance with the legal provisions in force at the date of closure of the site especially those related to the protection of workers and the environment.  
Closing measures 
The current Partial Temporary Closure Plan (approved by Resolution N° 1.304/2020) corresponds to an extension of the temporary closure plan of the Pampa Blanca Mining Site approved by Res Exe. N° 0802/2019, considering January 09, 2018, as the starting date of the temporary closure. The definitive total closure of the operation is estimated for the year 2044, according to Res Exe. N° 1.424/2015. The activities associated with this partial temporary closure are the removal of remaining explosives, closure of the explosive’s storage area, road closures, and installation of signage. During the shutdown period there will be monthly visual inspections and an inspection after relevant natural events, such as earthquakes, heavy rains or other.
The last report of closure mine plan includes all closure measures and actions included in the documents of the Environmental Qualification Resolution (RCA) and sectorial resolutions, including the closure plans approved by Resolution No. 1424/2015. The closure measures and actions are presented below. See Table 17-5.

Table 17-5. Closure measures and actions of the Closure Plan for the Pampa Blanca Mine for the remaining installations. 

InstallationClosure measureDescriptionFountain
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Mine (Caliche)Overload deposition and
Leaching heap materials as sector backfill
already exploited.		Overhead deposited on sites
Previously used in mine operation		Resolution No. 0292/2023 RCA 278/2010
Explosives removal
Remnants and closure of powder magazine.		The trigger storage enclosure shall be closed,
detonating cord and		Resolution No. 0292/2023 RCA 278/2010
Road closuresClosing parapet with overload at the main entrances. The parapet will have a volume of 5.25 m3 triangular sectionResolution No. 0292/2023 RCA 278/2010
SignageInstallation of Signage indicating the prohibition of incomeResolution No. 0292/2023 RCA 278/2010
LeachingSlope stabilization of leaching pilesOnce the Closure Plan has begun, your risk will be evaluated and analyzed, taking measures to ensure the stabilityResolution No. 0292/2023 RCA 278/2010
In COM I protect and / or remove structures, ponds, panels, equipment, and electrical systems.It will be dismantled (in if necessary)Resolution No. 0292/2023 RCA 278/2010
Drying pools in COMThey will remain full until they dry by evaporation.Resolution No. 0292/2023 RCA 278/2010
Removal of pipes and pumpsElimination of hydraulic and electrical irrigation systems and solution managementResolution No. 0292/2023 RCA 278/2010
Removal and de-energization of power linesConnections to electrical substations will be removedResolution No. 0292/2023 RCA 278/2010
Road closuresClosing parapet with overload at the main entrances the parapet will have a volume of 5.25 m3 Triangular sectionResolution No. 0292/2023 RCA 278/2010
SignageInstallation of Signage indicating the prohibition of incomeResolution No. 0292/2023 RCA 278/2010
Industrial water supplyRemoval of structures, panels, system
electrical and equipment.		Removal of structuresResolution No. 0292/2023
Removal of pipes and pumpsRemoval of structuresResolution No. 0292/2023
Removal and de-energization of power linesConnections to the Electrical substationsResolution No. 0292/2023
Road closuresClosing parapet with overload on Main Entrances
The parapet will have a volume of 5.25 m3
Triangular section		Resolution No. 0292/2023
SignageInstallation of Signage indicating the prohibition of incomeResolution No. 0292/2023
Iodide plantSafeguarding and/or removal of structures, ponds, panels, equipment, substations, and electrical systemsIt will be dismantled
Structures		Resolution No. 0292/2023
De-energization of installationsThe Connections to the Substations ElectricalResolution No. 0292/2023
Safeguarding and dismantling of buildingsIt will be dismantled StructuresResolution No. 0292/2023
Road closuresClosing parapet with overload on Main Entrances
The parapet will have a Volume of 5.25 m3 Triangular section		Resolution No. 0292/2023
SignageInstalling Señaléticas indicating the Prohibition of incomeResolution No. 0292/2023
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Evaporation poolsRemoval of metal structures, pipes,
pumps, electrical systems, and equipment		Removal of structures
(if necessary)		Resolution No. 0292/2023
De-energization of installationsThe Connections to the Substations ElectricalResolution No. 0292/2023
Road closuresClosing parapet with Main Entrances
The parapet will have a Volume of 5.25 m3 Triangular section		Resolution No. 0292/2023
SignageInstallation of Signage indicating the prohibition of incomeResolution No. 0292/2023
Support facilitiesSystem retirement electrical and StructuresConnections to the
Electrical substations		Resolution No. 0292/2023
De-energization of installationsThe Connections to substations ElectricalResolution No. 0292/2023
Hazardous Waste Removal and Final DisposalWaste Removal Dangerous from Patio authorized to Final ProvisionResolution No. 0292/2023
Non-Hazardous Waste RemovalWaste Removal Non-Hazardous from Patio authorized to Final ProvisionResolution No. 0292/2023
Source: Res Exe. N°0292/2023

There are no post-closure commitments associated with sectoral resolutions or environmental qualification resolutions (RCA).

1.Risk analysis  
SERNAGEOMIN, in consideration of Law 20,551 and Supreme Decree No. 41/2012, requests owners to carry out a risk assessment that considers the impacts on the health of people and the environment in the context of the closure of the mining site at the end of its useful life. This risk assessment was carried out considering the Risk Assessment Methodology for Mine Closure currently in force. The results of the evaluation indicate that the risks associated with the remaining facilities of the Pampa Blanca Slaughter are indicated below:
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Table 17-6. Risk assessment of the main facilities of the Pampa Blanca Site
Registration
Risks
Level
Significance


MR1
MR1. P
To people for failure in the slope of the pit, which exceeds the exclusion zone due to an earthquake
Low
Not significant
MR1.MA
To the environment due to fault in the slope of the pit, which exceeds the exclusion zone due to an earthquake
Low
Not significant


MR2
MR2. P
To people for infiltration of DAR from the mine
Low
Not significant
MR2.MA
To the environment by infiltration of DAR from the mine
Low
Not significant
Leaching piles


DE1
DE1. P
People from groundwater pollution due to rain
LOW
Non-Significant
DE1.MA
To the Environment due to groundwater pollution due to rain
LOW
Non-Significant


DE2
DE2. P
People for groundwater contamination due to flooding
LOW
Non-Significant
DE2.MA
To the Environment due to groundwater pollution due to a flood
LOW
Non-Significant


DE3
DE3. P
People due to emissions of particles into the atmosphere due to wind
LOW
Non-Significant
DE3.MA
To the Environment due to emissions of particles into the atmosphere due to wind
LOW
Non-Significant


DE4
DE4. P
People for surface water pollution due to heavy rain
LOW
Non-Significant
DE4.MA
To the Environment due to contamination of surface water due to heavy rain
LOW
Non-Significant

TRS Pampa Blanca 2024
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Registration
Risks
Level
Significance


DE5
DE5. P
People due to flooding of surface water
LOW
Non-Significant
DE5.MA
To the Environment due to flooding of surface water
LOW
Non-Significant


DE6
DE6. P
People due to water erosion due to heavy rain or delayed snowmelt
LOW
Non-Significant
DE6.MA
To the Environment due to water erosion due to rain or heavy delayed snowmelt
LOW
Non-Significant

DE7
DE7. P
People by landslide because of an earthquake.
LOW
Non-Significant
DE7.MA
To the Environment by landslide due to an earthquake.
LOW
Non-Significant
Solar evaporation pools


DE3

DE3. P
People for particulate matter suspended by wind

Low

Not significant

DE3.MA
To the Environment for particulate matter suspended due to wind

Low

Not significant


DE6

DE6. P
People due to slope failure due to water erosion

Low

Not significant

DE6.MA
To the Environment due to slope failure due to water erosion

Low

Not significant

DE7

DE7. P

People due to slope failure due to an earthquake

Low

Not significant
    
Registration
Risks
Level
Significance

DE7.MA
To the Environment due to slope failure due to an earthquake

Low

Not significant
Discard salts


DE3

DE3. P
People for particulate matter suspended by wind

Low

Not significant

DE3.MA
To the Environment for particulate matter suspended due to wind

Low

Not significant


DE6

DE6. P
People due to slope failure due to water erosion

Low

Not significant

DE6.MA
To the Environment due to slope failure due to water erosion

Low

Not significant


DE7

DE7. P

People due to slope failure due to an earthquake

Low

Not significant

DE7.MA
To the Environment due to slope failure due to an earthquake

Low

Not significant
TRS Pampa Blanca 2024
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17.5.2 Closing costs
The total amount of the closure of the Pampa Blanca mine site, considering closure detail in the valorization of de closure plan approved by Res Exe. N°0292/2023, sum 42.841 UF:
Table 17-7. Pampa Blanca Mine site closure Costs
Item  
Total (UF) 
Total direct closing cost 21,555
Indirect cost and engineering 2,155
Contingencies (20% CD + CI) 5,928
Subtotal 29,638
IVA (19%)  5,361
Closing Plan Amount (UF)  35,269
Source: Valorization of de closure plan approved by Res Exe. N°0292/2023, 

Table 17-8. Post-closure costs of Pampa Blanca
ArticleTotal (UF)
Cost them directly4,628
Indirect costs and administration463
Contingencies1,273
VAT (19%)1,209
Contribution to the amount of Post Closing (UF)7,572

The result of the calculation of the useful life for the Pampa Blanca mine according to the Res Exe. N°0292/2023 is 30 years. The constitution of the guarantees will be carried out as follows.
The end of operations will be 2035, and the closure period will be from 2036 to 2040. 




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Table 17-9. Constitution of the Guarantees of Pampa Blanca Mine Closure Plan.
YearGuarantee UF
716.626
818.646
920.722
1022.855
1125.046
1227.297
1329.608
1431.982
1534.419
1634.924
1735.438
1835.959
1936.487
2036.572
2136.659
2238.120
2338.681
2439.249
2539.826
2640.412
2741.006
2841.608
2942.220
3042.841
3142.841
3242.841
3342.841
3442.841
3542.841
Source: Valorization of de closure plan approved by Res Exe. N°0292/2023.


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18 CAPITAL AND OPERATING COSTS
This section contains forward-looking information related to capital and operating cost estimates for the Project. The material factors that could cause actual results to differ materially from the conclusions, estimates, designs, forecasts or projections in the forward-looking information include any significant differences from one or more of the material factors or assumptions that were set forth in this section including prevailing economic conditions continue such that unit costs are as estimated in constant (or real) dollar terms, projected labor and equipment productivity levels and that contingency is sufficient to account for changes in material factors or assumptions.
The main facilities for producing iodine and nitrate salts at the Pampa Blanca Site are as follows:
Caliche Mining
Heap Leaching
Iodide & Iodine Plants
Solar Evaporation Ponds
Water Resource Provision
Electrical Distribution System
General Facilities
18.1.CAPITAL COSTS
The main facilities are already developed, it is necessary to generate the reopening of this facilities. These facilities are for the production operations of Iodine and nitrate salts, include caliche extraction, leaching, water resources, Iodide production plant, solar evaporation ponds, as well as other minor facilities. Offices and services include, among others, the following: common areas, supply areas, powerhouse, laboratory and warehouse.
The capital cost that will be invested in 2024 is about USD 42 million with the relative expenditure by major category as shown in Table 18-1.

Table 18-1. Summary of Capital Expenses for the Pampa Blanca Operations 2024
Capital Cost
% TotalMM USD
Category100%42
Caliche Mining (*)22%9.5
Heap Leaching21%9.0
Iodide & Iodine Plant36%15.3
Solar Evaporation Ponds15%6.2
Water Resources Provision1%0.4
Seawater
5%2.0


18.1.1 Caliche Mining
SQM produces salts rich in iodide in Pampa Blanca and iodine at Nueva Victoria, near Iquique, Chile, mineral caliche extracted from mines at Pampa Blanca.
Capital investment in the mine is primarily for buildings and support facilities and associated equipment. The equipment including trucks, front loaders, bulldozers, drills, wheeldozers and motor graders has a finished useful life.

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18.1.2 Heap Leaching
The leach piles are made up of platforms (normally 90 x 500 m, with perimeter parapets and with a bottom waterproofed with HDPE membranes), which are loaded with the necessary caliche and are irrigated with different solutions (water, mixture or intermediate solution of piles).
The Mine Operation Centers (COM) are a set of leaching heaps that have brine accumulation ponds, recirculated “feeble brine” ponds, industrial water ponds and their respective pumping systems.
Primary capital expenditure is in the form of piping, electrical facilities and equipment, pumps, ponds, and support equipment.
18.1.3 Iodide and Iodine Plants
The main investment in the Iodide Plants is found in tank and decanter equipment, pumps and piping, equipment and electrical facilities, buildings and well.

18.1.4 Solar Evaporation Ponds
These ponds in the industrial area of Sur Viejo and receive the “Feeble Brine” fraction (BF) generated in the process of obtaining iodide, which is transported approximately 20 kilometers each.

18.1.5 Water Resources
Primary investment is in piping, pumps, buildings and wells.
18.2.FUTURE INVESTMENT
With an investment of US$68 million, the initiative aims to reopen the existing mining areas to produce iodide, iodine and salts rich in nitrates at the Pampa Blanca Site.
The project corresponds to a modification of the Pampa Blanca Faena consisting of:
1)There are no new mining areas.
2)New iodide production plant (1,500 t/y each).
3)There are no new Evaporation ponds.
Additional capital for the Long Term is estimated to be USD 68 million. The operating cost is presented in Table 18-2:
    Table 18-2 Estimated Investment
Investment (MUS$)
2025
2026
2027
2028
2029
2030
2031-2040
TOTAL
Pampa Blanca8345553868

18.3.OPERATING COST
The main costs to produce Iodine and Nitrates involve the following components: common production cost for iodine and nitrates, such as Mining, Leaching and Seawater, production cost of iodine in the plant, and the production cost of nitrate before processing at the Coya Sur site.
The production cost of nitrate at Coya Sur Plant and the processing of extra solar salt are added. To the costs indicated above, have been added the Depreciation and Others.
Estimated aggregate unit operating costs are presented in Table 18-3. These are based on historical unit operating costs for each of the sub-categories listed above.
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Over the Long Term, total operating costs are expected to be almost equally apportioned amongst the three primary categories (Common; Iodine Production and Transport; Nitrate Production and Transport).
Table 18-3 Pampa Blanca Operating Cost
Cost CategoryEstimated Unit Cost
Common (Mining / Leaching/ Water)
6.44 US$/Ton caliche
Iodine Production (including transport to ports)
32,100 US$/Ton iodine
Nitrates Production
85 US$/Ton nitrate
Nitrates Transport to Coya Sur
14 US$/Ton nitrate

19 ECONOMIC ANALYSIS
This section contains forward-looking information related to economic analysis for the Project. The material factors that could cause actual results to differ materially from the conclusions, estimates, designs, forecasts or projections in the forward-looking information include any significant differences from one or more of the material factors or assumptions that were set forth in this sub-section including estimated capital and operating costs, project schedule and approvals timing, availability of funding, projected commodities markets and prices.
19.1PRINCIPAL ASSUMPTIONS
Capital and operating costs used in the economic analysis are as described in Section 18. Sales prices used for Iodine and Nitrates are as described in Section 16. A 5.3% discount rate was used for the cashflow and is deemed reasonable to account for cost of capital and project risk. A 28% income tax rate was considerate and all costs, prices, and values shown in this section are in 2024 US$.
19.2PRODUCTION AND SALES
The estimated production of iodine and nitrates for the period 2025 to 2040 is presented in Table 19-1.
19.3PRICES AND REVENUE
An average sales price of 42.0 USD/kg (42,000 USD/tonne) was used for sales of Iodine based on the market study presented in in Section 16. This price is assessed as FOB port.
As a vertically integrated company, nitrate production from the mining operations are directed to the plant at Coya Sur for the production of specialty fertilizer products. An imputed sales price of 323 USD/Ton was assumed for nitrates salts for fertilizer based on an average sales price of 820 USD/ton for finished fertilizer products sold at Coya Sur, less 497 USD/ton for production costs at Coya Sur.
These prices and the revenue streams derived from the sale of iodine and nitrates is shown in Table 19-2.
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Table 19-1. Pampa Blanca Long Term of Mine Production
MATERIAL MOVEMENTUNITS2025202620272028202920302031-2040TOTAL
Pampa Blanca Sector Ore TonnageMt5.55.55.55.55.55.552.385.3
Iodine (I2) in situppm450437422416409399374392
Average grade Nitrate Salts (NaNO3)%7.0%7.0%7.0%6.0%6.0%6.0%5.0%5.4%
TOTAL ORE MINED (CALICHE)Mt5.55.55.55.55.55.552.385.3
Iodine (I2) in situkt2.52.42.32.32.22.219.533.5
Yield process to produce prilled Iodine%72.0%72.0%72.0%71.0%70.0%70.0%67.0%69.0%
Prilled Iodine producedkt1.81.71.71.61.61.513.223.1
Nitrate Salts in situkt3913743583473303192,4954,613
Yield process to produce Nitrates Salts%35.0%35.0%34.0%34.0%33.0%33.0%33.0%33.3%
Nitrate Salts for Fertilizerskt1371291221171101068141,535



Table 19-2. Pampa Blanca Iodine and Nitrate Price and Revenues
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PRICESUNITS2025202620272028202920302031-2040TOTAL
IodineUS$/t42,00042,00042,00042,00042,00042,00042,00042,000
Nitrates delivered to Coya SurUS$/t323323323323323323323323
REVENUEUNITS2025202620272028202920302031-2040TOTAL
IodineUS$M757370686765553970
Nitrates delivered to Coya SurUS$M444239383634263496
Total RevenuesUS$M119115109106102998161,466


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19.4OPERATING COSTS
Operating costs associated with the production of iodine and nitrates at Pampa Blanca are as described earlier in Section 18 and are incurred in the following primary areas:
1. Common
2. Iodine Production
3. Nitrate Production
Additional details on operating costs may be found in Section 18.3. Unit costs for each of these unit operations is shown in Table 19-3.
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Table 19-3. Pampa Blanca Operating Costs.
COSTSUNITS2025202620272028202920302031-2040TOTAL
COMMON
MiningUS$M181818181818175285
Leaching w/o WaterUS$M6666666198
Water w/o EnergyUS$M111111111111102166
Total Mining CostsUS$M353535353535337550
IODINE PRODUCTION
Solution CostUS$M333333333333322521
Iodide PlantUS$M1111101010991142
Iodine PlantUS$M6666554579
Total Iodine Production CostUS$M505049494848447741
Total Iodine Production CostUS$/kg Iodine27.928.629.53030.631.33432.1
NITRATE PRODUCTION
Solution CostUS$M3222221529
Ponds and preparationUS$M6666553872
Harvest productionUS$M2222221528
Others (G&A)US$M12
Transport to Coya SurUS$M2222211121
Total Nitrate Production CostUS$M13131212111080151
Total Nitrate Production CostUS$/t Nitrate9999999999999999
Closure AccretionUS$M0
TOTAL OPERATING COSTUS$M636261605959528893

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19.5CAPITAL EXPENDITURE
Much of the primary capital expenditure in the Pampa Blanca Project has been completed.
The most significant proposed future capital expenditure is for the seawater pipeline to support the proposed TEA Expansion Project. This investment is expected to need USD 68 million for 2025-2040.
Additional details on capital expenditures for the Pampa Blanca Project can be found in Section 18.1 and Section 18.2. The estimated capital expenditure for the Long Term (2025 to 2040) is presented in Table 18-2.
19.6CASHFLOW FORECAST
The cashflow for the Pampa Blanca Project is presented in Table 19-4. The following is a summary of key results from the cashflow:
Total Revenue: estimated to be USD 1,466 million including sales of iodine and nitrates
Total Operating Cost: estimated to be USD 893 million.
EBITDA: estimated at USD 573 million
Tax Rate of 28% on pre-tax gross income
Capital Expenditure estimated at USD 68 million
Net Change in Working Capital is based on two months of EBITDA.
A discount rate of 5.3% was utilized to determine NPV. The QP deems this to be a reasonable discount rate to apply for this TRS which reasonable accounts for cost of capital and project risk.
After-tax Cashflow: The cashflow is calculated by subtracting all operating costs, taxes, capital costs, interest payments, and closure costs from the total revenue.
Net Present Value: The after tax NPV is estimated to be USD 273 million at a discount rate of 5.3%.
The QP considers the accuracy and contingency of cost estimates to be well within a Prefeasibility Study (PFS) standard and sufficient for the economic analysis supporting the Mineral Reserve estimate for Pampa Blanca.
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Table 19-4. Estimated Net Present Value (NPV) for the Period

REVENUEUNITS2025202620272028202920302031-2040TOTAL
Total RevenueUS$M119115109106102998161,466
COSTS
Total Mining CostsUS$M353535353535337550
Total Iodine Production CostUS$M505049494848447741
Total Nitrate Production CostUS$M13131212111080151
Closure AccretionUS$M
TOTAL OPERATING COSTUS$M636261605959528893
EBITDAUS$M565248464340288573
DepreciationUS$M2234544868
Pre-Tax Gross IncomeUS$M545045423836240506
Taxes28%15141312111067142
Operating IncomeUS$M393633302726173364
Add back depreciationUS$M2234544868
NET INCOME AFTER TAXESUS$M413836343230221432
Total CAPEXUS$M8345553868
Closure CostsUS$M22
Working CapitalUS$M0-1-10-10-4(7)
Pre-Tax CashflowUS$M485045413836253511
After-Tax CashflowUS$M333632292826185369
Pre-Tax NPVUS$M379
After-Tax NPVUS$M273
Discount RateUS$M5.3%

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19.7SENSITIVITY ANALYSIS
The sensitivity analysis was carried out by independently varying the commodity prices (Iodine, Nitrate), operating cost, and capital cost. The results of the sensitivity analysis are shown in Figure 19-1 shows the relative sensitivity of each key metric.
Figure 19-1. Sensitivity Analysis
chart-bcbb7d27c3734b3f8d8.jpg
As seen in the above figure, the project NPV is equally sensitive to operating cost and commodity price while being least sensitive to capital costs. This is to be expected for a mature, well-established project with much of its infrastructure already in place and no significantly large projects currently planned during the LOM discussed in this Study. Both iodine and nitrate prices have a similar impact on the NPV with nitrate prices having a slightly larger impact.

20 ADJACENT PROPERTIES
The company's deposits are laid on flat land or "pampas" at the Pampa Blanca mine site and facilities cover a mine area of 51,201 hectares.
Pampa Blanca mine site has an approximate area of 104.41 km2 (10,441 Ha).
Prospect deposits (see Figure 20-1, Figure 20-2.) corresponding to the Pampa Blanca mine properties are as follows:
Celia
Condell
Paulo
Miedo
Lenka
Carbonato
Colina
TRS Pampa Blanca 2024
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Chacabuco
Copo
Condell
Aurelia
Paulo IV
Estaca Boliviana
Celia
Of all the areas prospected in the Sierra Gorda sector, the following have been explored:
Pampa Blanca
Blanco Encalada
Baquedano
Qb. San Cristobal
Eugenia (Exolympia)
Ampliación Carbonato
Exploration program results show that these prospects reflect a mineralized trend hosting nitrate and iodine. On the other hand, exploration efforts are focused on possible metallic mineralization beneath the caliche. The area has significant potential for metallic mineralization, especially copper and gold. Exploration has generated discoveries that, in some cases, may lead to exploitation, sales of the discovery, and generation of royalties in the future. Within this framework, in 2013, we recorded a royalty sale of the Antucoya project to Antofagasta Minerals (copper mining).
Within the boundary belonging to SQM-Pampa Blanca, as presented in Figure 20-2., it is stated that there are other properties adjacent to the Project that is exploited by others, and there are some mining rights. In total there are three mining lots, which include:
1. Algorta Norte S.A. is a joint venture between ACF Minera S.A. and Toyota Tsusho:
Surface
2. Antofagasta Minerals;
Surface
Rencoret Mine
Surface

TRS Pampa Blanca 2024
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Figure 20-1. Pampa Blanca Adjacent Properties
image_133.jpg


TRS Pampa Blanca 2024
Pag. 183

Figure 20-2. Other properties adjacent to the Project that is exploited by others
image_134.jpg

TRS Pampa Blanca 2024
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21 OTHER RELEVANT DATA AND INFORMATION
The QP is not aware of any other relevant data or information to disclose in this TRS.

22 INTERPRETATION AND CONCLUSIONS
The work done in this report has demonstrated that the mine, heap leach facility and the iodine and nitrate operations correspond to those of a technically feasible and economically viable project. The most appropriate process route is determined to be the selected unit operations of the existing plants, which are otherwise typical of the industry.
The current needs of the nitrate and iodine process, such as power, water, labor, and supplies, are met as this is a mature operation with many years of production supported by the current project infrastructure. As such, performance information on the valuable nitrate and iodine species consists of a significant amount of historical production data, which is useful for predicting metallurgical recoveries from the process plant. Along with this, metallurgical tests are intended to estimate the response of different caliche ores to leaching.
Mrs. Marco Fazzi QP of Reserves, concludes that the work done in the preparation of this technical report includes adequate details and information to declare the Mineral Reserves. In relation to the resource treatment processes, the conclusion of the responsible QP, Gino Slanzi, is that appropriate work practices and equipment, design methods and processing equipment selection criteria have been used. In addition, the company has developed new processes that have continuously and systematically optimized its operations.
22.1RESULTS
Geology and Mineral Resources
1.The Pampa Blanca geology team has a clear understanding of mineralization controls and the geological and deposit related knowledge has been appropriately used to develop and guide the exploration, modeling and estimation processes.
2.Sampling methods, sample preparation, analysis and security were acceptable for mineral resource estimation. The collected sample data adequately reflect deposit dimensions, true widths of mineralization, and the style of the deposits. Sampling is representative of the Iodine and Nitrate Grades.

3.The average mineral resource concentrations are above the cut- off benefit of 3.0 USD/t, reflecting that the potential extraction is economically viable.

Metallurgy and Mineral Processing
According to Gino Slanzi Guerra, the QP in charge of metallurgy and resource treatment:
1.There is a duly documented verification plan for the cover system to limit infiltration during leaching. The document establishes installation and leak detection procedures in accordance with environmental compliance criteria.
2.Metallurgical test work performed to date has been adequate to establish appropriate processing routes for the caliche resource. The metallurgical test results show that the recoveries are dependent on the saline matrix content and, on the other hand, the maximization of this is linked to the impregnation cycle which has been studied, establishing irrigation scales according to the classified physical nature. The derived data are suitable for the purpose of estimating recovery from mineral resources.

3.Based on the annual, short- and long-term production program, the yield is estimated for the different types of material to be exploited according to the mining plan, according to their classification of physical and chemical properties, obtaining a projection of recoveries that is considered quite adequate for the resources.
Reagent forecasting and dosing are based on analytical processes that determine ore grades, valuable element content and impurity content to ensure that the system's treatment requirements are effective. These are translated into consumption rate factors that are maturely studied.
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Since access to water can be affected by different natural and anthropogenic factors, the use of seawater is a viable alternative for future or current operations. However, this may increase operating costs, resulting in additional maintenance days.
During operations, the content of impurities fed to the system and also the concentration in the mother liquor is monitored in order to eventually detect any situation that may impact the treatment methodologies and the characteristics of its products.
22.2RISKS
Geology and Mineral Resources
As mining proceeds into new areas, such as Pampa Blanca Sector 5, the production, dilution, and recovery factors may change based on geological, geometallurgial and operational factors. These factors and mining costs should be evaluated on a sector-by-sector basis.
Metallurgy and Mineral Processing
The risk that the process, as currently defined, will not produce the expected quantity and/or quality required. However, exhaustive characterization tests have been carried out on the treated material and, moreover, at all stages of the process, controls are in place to manage within certain ranges a successful operation.
The risks of a meteorological event or changes in local climatic conditions, which may result in lower production due to lower availability of the treated resource in the process plants.
The risk that the degree of impurities in the natural resources may increase over time more than predicted by the model, which may result in non-compliance with certain product standards. Consequently, it may be necessary to incorporate other process stages, with the development of previous engineering studies, to comply with the standards.
22.3SIGNIFICANT OPPORTUNITIES
Geology and Mineral Resources
There is a big opportunity to improve the resource estimation simplicity and reproducibility using the block model approach not only in the case of smaller drill hole grids of 50 x 50 m and up to 200 x 200m, but also for larger drill hole grids to avoid separating the resource model and databases by drill hole spacing, bringing the estimation and management of the resource model to industry standards.
Metallurgy and Mineral Processing
1.Improve heap slope irrigation conditions to increase iodine and nitrate recovery.
2.Use of clayey materials (low permeability) available in discards as soil cover for infiltration management.


23 RECOMMENDATIONS
23.1GEOLOGY AND MINERAL RESOURCES

Continue with the QAQC program using certified standards to ensure the control of precision, accuracy and contamination in the chemical analysis of SQM Caliche Yodo Laboratory with the objective of having an auditable database according to industry best practices.
Expand the block model approach for resource estimation to larger drillhole grids to avoid separating the resource model and databases by drillhole spacing.
Audit with an external company of the entire resource estimation process, that is, expert review of drilling database, resource estimation, and reserve valuation
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23.2METALLURGY AND MINERAL PROCESSING

Regarding irrigation, alternatives that allow an efficient use of water should be reviewed, considering the irrigation of the lateral areas of the heaps to increase the recovery of iodine and nitrates.
A relevant aspect is the incorporation of seawater in the process, a decision that is valued given the current water shortage and that ultimately is a contribution to the project, however, a study should be made of the impact of processing factors such as impurities from this source.
It is advisable to carry out tests to identify the hydrogeological parameters that govern the behavior of the water inside the heap. Review the properties of the mineral bed, which acts as a protector of the binders at the base of the heaps, which is currently a fine material called "chusca", which could be replaced by classified particulate material, favoring the percolability of the solutions and saving water.
It is considered important to evaluate the leachable material through heap leaching simulation, which allows the construction of a conceptual model of caliche leaching with a view to secondary processing of the riprap to increase the overall recovery.
It is contributive and relevant to work on the generation of models that represent heap leaching, the decrease in particle size (ROM versus Scarious granulometry) and, therefore, of the whole heap and the simultaneous dissolution of different species at different rates of nitrate iodine extraction.
With respect to generating material use options, detailed geotechnical characterization of the available clays within the mine property boundaries is suggested to assess whether there are sufficient clay materials on site to use as a low permeable soil liner bed under the leach pad.
Environmental issues include leachate or acid water management, air emissions management, tailings dump management, and leachate riprap.
All the above recommendations are considered within the declared CAPEX/OPEX and do not imply additional costs for their execution.
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24 REFERENCES
Chong, G., Gajardo, A., Hartley, A., Moreno, T. 2007. Industrial Minerals and rocks. In Moreno, T. & Gibbons, W. (eds) The Geology of Chile 7, 201-214
Ericksen, G.E. 1981. Geology and origin of the Chilean nitrate deposits. U.S. Geological Survey Professional Paper 1188-B.
Fiesta, B. 1966. El origen del salitre de Chile. Sociedad Española de Historia Natural Boletín, Sección Geológica 64(1), 47-56.
Mueller, G. 1960. The theory of formation of north Chilean nitrate deposits through ((capillary concentration)). International Geological Congress, 21st, Copenhagen 1960, Report 1, 76-86.
Pueyo, J.J.; Chong, G.; Vega, M. 1998. Mineralogía y evolución de las salmueras madres en el yacimiento de nitratos Pedro de Valdivia, Antofagasta, Chile. Revista Geológica de Chile, Vol. 25, No. 1, p. 3-15.
Reich, M., Snyder, G.T., Alvarez, F., Pérez, A., Palacios, C., Vargas, G., Cameron, E.M., Muramatsu, Y., Fehn, U. 2013. Using iodine to constrain supergen uid sources in arid regions: Insights from the Chuquicamata oxide blanket. Economic Geology 108, 163-171.
Reich, M., Bao,H. 2018. Nitrate Deposits of the Atacama Desert: A Marker of Long-Term Hyperaridity. Elements, Vol. 14, 251–256

25 RELIANCE ON INFORMATION PROVIDED BY REGISTRANT
The qualified person has relied on information provided by the registrant in preparing its findings and conclusions regarding the following aspects of modifying factors:
1.Macroeconomic trends, data, and assumptions, and interest rates.
2.Projected sales quantities and prices.
3.Marketing information and plans within the control of the registrant.
Environmental matter outside the expertise of the qualified person.

TRS Pampa Blanca 2024
Pag. 188