EX-96.1

EX-96.1 19 d222316dex961.htm EX-96.1 EX-96.1

Exhibit 96.1

INITIAL ASSESSMENT REPORT

(REVISED)

FORT CADY BORATE PROJECT, SAN

BERNARDINO COUNTY, CALIFORNIA

Submitted to:

AMERICAN PACIFIC BORATE LTD.

Report Date:

February 7, 2022

Report Effective Date:

October 15, 2021

Millcreek Mining Group

1011 East Murray Holladay Road

Salt Lake City, Utah

84117

Tel: (801) 904-2260

Fax: (801) 904-2261

Email info@millcreekmg.com

www.millcreekmg.com

Author:

STEVEN B. KERR, CPG

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DATE AND SIGNATURE PAGE

This report titled “Initial Assessment Report, Fort Cady Borate Project, San Bernardino California” and dated October 18, 2021, was prepared and signed by:

(Signed & Sealed)

Steven B. Kerr CPG

Principal Consultant – Geology

Millcreek Mining Group

Dated at Bountiful, Utah

October 18, 2021

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TABLE OF CONTENTS


1	EXECUTIVE SUMMARY		1-1

2	INTRODUCTION		2-1

3	PROPERTY DESCRIPTION		3-4

	3.1	MINERAL TENURE	3-5

4	ACCESSIBILITY, CLIMATE, LOCAL RESOURCES, INFRASTRUCTURE AND PHYSIOGRAPHY		4-1

5	HISTORY		5-1

6	GEOLOGICAL SETTING, MINERALIZATION AND DEPOSIT		6-1

	6.1	REGIONAL SETTING	6-1

	6.2	MINERALIZATION	6-3

	6.3	MINERAL DEPOSIT	6-4

7	EXPLORATION		7-1

	7.1	HISTORIC DRILLING	7-1

	7.2	APBL DRILLING	7-3

	7.3	HYDROGEOLOGY	7-7

		7.3.1 Hydrologic setting	7-7

		7.3.2 Project Area Wells	7-8

		7.3.3 Hydraulic Properties	7-9

8	SAMPLE PREPARATION, ANALYSES AND SECURITY		8-1

	8.1	SAMPLING METHOD AND APPROACH	8-1

	8.2	SAMPLE PREPARATION, ANALYSES AND SECURITY	8-2

9	DATA VERIFICATION		9-1

10	MINERAL PROCESSING AND METALLURGICAL TESTING		10-1

	10.1	MINERAL CHARACTERISTICS	10-1

	10.2	SOLUTION MINING	10-1

	10.3	PROCESSING	10-2

11	MINERAL RESOURCE ESTIMATES		11-1

	11.1	INTRODUCTION	11-1

	11.2	RESOURCE DATABASE	11-1

	11.3	GEOLOGIC MODEL	11-1

	11.4	GRADE ESTIMATION & RESOURCE CLASSIFICATION	11-3

	11.5	MODEL VALIDATION	11-4

	11.6	DENSITY MEASUREMENTS	11-6

	11.7	CUT-OFF GRADE	11-6

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	11.8	MINERAL RESOURCE ESTIMATION	11-7

12	MINERAL RESERVE ESTIMATES		12-1

13	MINING METHODS		13-1

14	PROCESSING AND RECOVERY METHODS		14-1

15	INFRASTRUCTURE		15-1

16	MARKET STUDIES		16-1

	16.1	BORON MARKET	16-1

		16.1.1 Boron Market	16-1

		16.1.2 Boron Pricing	16-3

		16.1.3 Boric Acid Specification	16-3

	16.2	LITHIUM MARKET	16-4

		16.2.1 Lithium Production	16-4

		16.2.2 Pricing	16-4

	16.3	POTASH	16-5

		16.3.1 Production	16-5

		16.3.2 Pricing	16-5

		16.3.3 SOP Specification	16-6

	16.4	GYPSUM	16-6

		16.4.1 Production	16-7

		16.4.2 Pricing	16-7

	16.5	CONTRACTS	16-7

	16.6	MARKET ENTRY STRATEGY	16-8

17	ENVIRONMENTAL STUDIES, PERMITTING AND PLANS, NEGOTIATIONS, OR AGREEMENTS WITH LOCAL INDIVIDUALS OR GROUPS		17-1

18	CAPITAL AND OPERATING COSTS		18-1

19	ECONOMIC ANALYSIS		19-1

20	ADJACENT PROPERTIES		20-1

21	OTHER RELEVANT DATA AND INFORMATION		21-1

22	INTERPRETATION AND CONCLUSIONS		22-1

23	RECOMMENDATIONS		23-1

24	REFERENCES		24-1

25	RELIANCE ON INFORMATION PROVIDED BY THE REGISTRANT		25-1

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LIST OF TABLES


Table 1.1 Fort Cady Project Mineral Resource Estimate, October 15, 2021			1-9
Table 5.1 Duval Testing Results			5-2
Table 5.2 Mountain States Testing Injection Summary			5-2
Table 5.3 Mountain States Testing Recovery Summary			5-2
Table 5.4 Fort Cady Mineral Corporation Production Summary			5-3
Table 7.1 Historic Drilling Summary			7-2
Table 7.2 2017 APBL Drilling Summary			7-3
Table 8.1 Summary of QA/QC Control Samples			8-2
Table 11.1 Summary of Drilling Database			11-2
Table 11.2 Modelled Horizons			11-3
Table 11.3 Modelled Variograms			11-4
Table 11.4 Fort Cady Project Cut-off Grades			11-6
*Table 11.5 Fort Cady Project Mineral Resource Estimate, October 15, 2021**			11-8
Table 11.6 Uncontrolled Resources			11-9
Table 23.1 Recommended Drilling Budget			23-1

LIST OF FIGURES


Figure 1.1 Boron Pricing			1-11
Figure 1.2 Lithium Pricing			1-11
Figure 1.3 MOP and SOP Pricing			1-12
Figure 1.4 Gypsum Pricing			1-12
Figure 3.1 General Location Map			3-4
Figure 3.2 Land Title Ownership for the Fort Cady Project			3-6
Figure 6.1 Surface Geology in the Newberry Springs Area			6-1
Figure 6.2 Surface Geology Map for the Project Area			6-2
Figure 6.3 Fort Cady Resource Boundary			6-5
Figure 6.4 Long-section and Cross-section through the Fort Cady Deposit			6-6
Figure 6.5 Generalized Lithological Column for the Fort Cady Deposit			6-8
Figure 7.1 Fort Cady Drilling Locations			7-5
Figure 7.2 Cross-section Through the Fort Cady Deposit			7-6
Figure 7.3 Core Photo, 17FTCBL-014			7-6
Figure 7.4 Project Area Groundwater Basins and Surrounding Area Wells, Fort Cady Project, San Bernardino, CA			7-7

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Figure 8.1 Assay Results of Standard SRM1835			8-3
Figure 8.2 Assay Results of Standard SRM97b			8-3
Figure 8.3 Assay Results for SRC Standard CAR110/BSM			8-4
Figure 8.4 Assay Results for SRC Standard CAR110/BSH			8-4
Figure 8.5 Sample Blank Assay Results for Boron			8-5
Figure 8.6 Sample Blank Assay Results for Lithium			8-6
Figure 8.7 Duplicate Sample Results for Boron			8-6
Figure 8.8 Duplicate Sample Results for Lithium			8-7
Figure 8.9 HARD Diagram for APBL Duplicate Samples			8-7
Figure 8.10 SRC Duplicate Results			8-8
Figure 8.11 SRC Duplicates HARD Diagram			8-8
Figure 11.1 Grade Variation Swath Plots			11-5
Figure 11.2 Resource Classification for the Upper Mineralized Horizon (UMH)			11-10
Figure 11.3 Resource Classification for the Main Mineralized Horizon (MMH)			11-11
Figure 11.4 Resource Classification for the Intermediate Mineralized Horizon (IMH)			11-12
Figure 11.5 Resource Classification for the Lower Mineralized Horizon (LMH)			11-13
Figure 13.1 Block 2 Mining Sequence			13-2
Figure 15.1 Fort Cady Project Infrastructure			15-2
Figure 16.1 Current Borates Demand by End Use			16-2
Figure 16.2 Boron Pricing			16-3
Figure 16.3 Lithium Pricing			16-5
Figure 16.4 MOP and SOP Pricing			16-6
Figure 16.5 Gypsum Pricing			16-7
Figure 23.1 Proposed Drilling Locations			23-3

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1	EXECUTIVE SUMMARY

American Pacific Borates Limited (APBL) Is a publicly traded company listed on the Australian Securities Exchange under the symbol ABR. Through its wholly owned U.S. subsidiary, Fort Cady (California) Corporation (FCCC), the company is developing the Fort Cady Borate Project (the Project). The Project contains the largest known global deposit of colemanite not owned by the Turkish Government controlled entity, Eti Maden. Colemanite is a hydrated calcium borate mineral (2CaO • 3B₂O₃ • 5H₂O) found in evaporite deposits. Through in-situ leaching (ISL), FCCC will recover borates (boron-oxygen compounds), boric acid (H₃BO₃), lithium (Li), and other potential commodities.

This report presents the resources at the Fort Cady Borate Project. Reserves are not presented in this report since new dissolution tests are ongoing and work for a small-scale boron facility (SSBF) work is proceeding, both of which provide key inputs to the economic recoverability of the resources. This report has been prepared under the S-K 1300 rules and guidelines of the U.S. Securities and Exchange Commission (SEC) and will be used in supporting a listing on NASDAQ, under the name ‘5E Advanced Materials Inc.’.

The Fort Cady Borate deposit was first discovered in 1964. From 1977 through the early 2000s, the deposit has undergone exploration, pilot ISL testing, feasibility studies and limited production. APBL purchased a 100% interest in the Project in in May 2017 from Atlas Precious Metals Inc. Since that time, the Project has undergone additional exploration, permitting and development activities. APBL completed an exploration drilling program to validate previous exploration efforts and expand mineral resources. Following the drilling program, a JORC mineral resource estimate was prepared by Terra Modelling Services for the Project (December 2017). TMS later updated the JORC mineral resource estimate in December 2018.

In 2018, an initial feasibility under the JORC Code (Initial Study) for the Project was completed by APBL and reviewed by RESPEC Company LLC (RESPEC). Based on further engineering work, a second feasibility study (Second Study) was released in February 2021. None of the prior mineral resource estimates were Regulation S-K 1300 compliant.

The Project is located in the Mojave Desert region in eastern San Bernardino County, California. The project lies approximately 118 mi. northeast of Los Angeles near the town of Newberry Springs and is approximately 36 mi. east of the city of Barstow. Fort Cady resides in a highly prospective area for borate and Li mineralization and has a similar geological setting as Rio Tinto Borates’ Boron operations and Nirma Limited’s Searles Lake (Trona) operations, situated approximately 75 mi. west-northwest and 90 mi. northwest of the Project, respectively.

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The Project is located in the western Mojave Desert with arid, hot, dry sunny summers of low humidity and temperate winters. Elevation ranges from approximate 1,970 ft. to approximately 2,185 ft. above sea level. Basalt lava flows cover most of the higher elevations or hilltops with flat ground and drainages covered in pale, gray-brown, silty soils.

Access to the Project is via U.S. Interstate 40 (I-40), eastbound from Barstow to the exit for Newberry Springs. From the exit, travel continues eastward for 14.4 mi. on the National Trails Highway to County Road 20796 (CR20796). Travel continues south on CR20796 for 2.2 mi. to an unnamed dirt road bearing east for another 1.1 mi. to the mine office and plant site at the Project. Several other dirt roads connect to the dirt road leading to the mine office and to CR20796 that provide good access throughout the project area.

The Union Pacific Railroad runs subparallel to I-40 with a rail loadout located approximately 0.4 mi. west of CR20796. San Bernardino County operates six general aviation airports and commercial flight service is available through five airports in the greater Los Angeles area and in Los Vegas, NV. A dedicated cargo service airport, San Bernardino International Airport, is located approximately 65 mi. southwest of the Project.

Construction of an ISL mining operation and processing plant at the Project will require local resources of contractors, construction materials, employees and housing for employees, and energy resources. The Project has good access to numerous sizable communities between Barstow and the greater Los Angeles area offering excellent access to transportation, construction materials, labor, and housing.

Discovery of the Fort Cady borate deposit occurred in 1964 when Congdon and Carey Minerals Exploration Company found several zones of colemanite between the depths of 1,330 ft to 1,570 ft. below ground. In September 1977, Duval Corporation (“Duval”) initiated land acquisition and exploration activities near Hector, California,

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Duval commenced limited-scale solution mining in June 1981. An additional 17 production wells were completed between 1981 and 2001 which were used for injection testing and pilot-scale operations. FCMC became involved with the project with the view of commencing pilot-scale testing. The first phase of pilot plant operations was conducted between 1987 and 1988. Approximately 450 tonnes of boric acid were produced during this time. Given the promising results of the pilot-scale tests the project was viewed to be commercially viable. Concentrated permitting efforts for commercial-scale operations began in early 1990. Final approval for commercial-scale solution mining and processing was attained in 1994.

Extensive feasibility studies, detailed engineering and test works were subsequently undertaken in the late 1990’s and early 2000’s. This included a second phase of pilot plant operations between 1996 and 2001 during which approximately 1,800 tonnes of a synthetic colemanite product (marketed as CadyCal 100) were produced. Commercial-scale operations were not commissioned due to low product prices and other priorities of the controlling entity.

Over US$80 million has been spent on the Fort Cady Project, including license acquisition, drilling and mineral resource estimation, well testing, metallurgical testing, feasibility studies and pilot plant testing test work. In addition, the project has previously obtained all operating and environmental permits required for commercial solution mining operations to produce 90,000 short tons per annum of boric acid.

The project area is characterized by narrow faulted mountain ranges and flat valleys and basins, the result of tectonic extension that began approximate 17 million years ago. The Project lies within the Hector Basin of the Barstow Trough. The Barstow Trough, which is a structural depression is characterized by thick successions of Cenozoic sediments, including borate-bearing lacustrine deposits, with abundant volcanism along the trough flanks. As the basin was filled with sediments and the adjacent highland areas were reduced by erosion, the areas receiving sediments expanded, and playa lakes, characterized by fine-grained clastic and evaporitic chemical deposition, formed in the low areas at the center of the basins.

Mineralization occurs in the subsurface in a sequence of lacustrine sediments ranging in depths from 1,135 to 1,872 ft. below the surface. The mineralization is hosted by a sequence of mudstones and tuffs, consisting of variable amounts of colemanite, a calcium borate (2CaO • 3B₂O₃ • 5H₂O). Colemanite is the target mineral for this deposit and is found in evaporite deposits of alkaline lacustrine environments. Colemanite is a secondary alteration mineral formed from borax and ulexite. The colemanite is associated with thinly laminated siltstone, clay and gypsum beds containing an average of 9% calcite, 35% anhydrite plus 10% celestite (SrSO₄). In addition to colemanite and celestite, elevated levels of Li have been found through chemical analyses of drill samples.

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Boron is believed to have been sourced from thermal waters that flowed from hot springs in the region during times of active volcanism. These hot springs vented into the Hector Basin that contained a large desert lake. Borates were precipitated as the thermal waters entered the lake and cooled or as the lake waters evaporated and became saturated with boron. Colemanite being the least soluble mineral, would evaporate on the receding margins of the lake. The evaporite-rich sequence forms a consistent zone in which the borate-rich colemanite zone transgresses higher in the section relative to stratigraphic marker beds.

Based on drilling results, the deposit is elongate in shape and trends northwesterly, extending over an area of about 606 acres at an average depth of approximately 1,150 ft. to 1,312 ft. below surface. In plan view, the concentration of boron-rich evaporites is roughly ellipsoidal with the long axis trending N40°W to N50°W. Beds within the colemanite deposit strike roughly N45°W and dip about 10° or less to the southwest. Using an isoline of 5% B₂O₃, mineralization has an approximate width of 2,800 ft. and a length of 11,150 ft. with thickness ranging from 70 to 262 ft. (exclusive of barren interbeds).

In 1981 and 1982, Duval drilled five wells to be used in injection/recovery tests. Like previous drilling, the wells were rotary drilled through the overburden and cored through the evaporite sequence. Following coring, 5.5-inch casing was set through the cored interval. Duval drilled three more wells in 1992 and 1993. FCMC completed two drilling campaigns during their participation on the project between 1987 and 1996 as rotary holes for injection/recovery wells. Cuttings samples were collected for analysis on 5-foot intervals for holes three of the wells.

In May 2017, APBL completed 14 drill holes, confirmed previous drilling results, and expanded the mineral resource estimate at Fort Cady. Drilling through the overburden sequence was completed using rotary air blast drilling, followed by drilling HQ (2.5-inch) core through the evaporite sequence. The core was logged and evaluated using industry standard techniques. All drill holes were completed vertically with no greater than five degrees of deviation.

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Core logging was completed on all drill holes and included lithological and geotechnical logging. Downhole geophysical logs, including Gamma Ray, Induction and standard caliper were completed on all drill holes from surface to TD, with the exception of 17FTCBL009 where adverse hole conditions resulted in only partial geophysical logging. All core is logged and photographed according to industry standard procedures. A geotechnical drill hole, APBL023, was also completed in 2017. This well was cored its entire length and a geologic log was completed to define mineralized horizons.

There are 2,113 samples from the 2017 drilling program representing 1,713 ft. of core. In conjunction with the 2017 drilling program, 29 historical drill holes completed by Duval and four holes completed by FCMC have been utilized in the mineral resource estimate. There are 3,672 samples from the historic drilling representing a cumulative total 10,831.3 ft. of core. The QA/QC procedures for the historic drilling are unknown though the work products compiled during the historic drilling suggests it was carried out by competent geologists following procedures considered standard practice at that time.

For the 2017 drilling program, entire core sequences were sampled. Sample intervals were determined at the time of logging are based on changes in lithology, mineralogy, and bedding. Sample intervals range from 0.2 to 6.6 ft. with an overall average sample length of 2.66 ft. Following determination of sampling intervals, core was split in half using a core splitter. One half of the core is used for the analytical sample with the remaining half core being returned to the core box for archiving. Samples were dispatched by commercial carrier to the Saskatchewan Research Council (SRC) for geochemical analysis. All samples underwent a multi-element Inductively Coupled Plasma Optical Emission Spectroscopy (ICP-OES), using a multi-acid digestion. Boron undergoes a separate digestion where an aliquot of the sample is fused in a mixture of NaO₂/NaCO₃ in a muffle oven, then dissolved in deionized water, prior to analysis.

APBL submitted 415 control samples, in the form of certified standards, blanks and coarse duplicates. SRC also submitted 233 of their own internal control samples in the form of standards and pulp duplicates. The QA/QC program has shown the analyses are viable with a minimum of dispersion or contamination errors.

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During the site visit, the QP examined the core for five of the 2017 drill holes completed by ABL. Core has been safely stored in a designated storage building nearby the mine site office and is in good condition. The QP examined the core and compared the core to the geologic logs and sample interval records and found good agreement with the log descriptions and with no discrepancies with sample intervals.

The QP has done a visual check of drilling locations through Google Earth. Drill sites from the 2017 drilling program are still visible on imagery. Older sites completed by Duval and FCMC are not discernible on imagery. The QP checked historic drilling location data to ensure these records had been properly converted to UTM coordinates.

The QP was provided drilling records, sample intervals, and assay results in Excel Workbook files used as input for the drill hole database. Through a variety of data checks drill hole information was evaluated for duplicate entries, incorrect intervals, lengths, or distance values less than or equal to zero, out-of-sequence intervals and intervals or distances greater than the reported drill hole length. A review comparing original field logs and assay reports showed the data to have been transcribed accurately into the Excel files.

In-situ solution mining depends on void spaces and porosity, permeability, ore zone thickness, transmissivity, storage coefficient, piezometric surface, and hydraulic gradient as well as reaction and extraction method efficiencies. APBL intends to use solution mining by injecting an acid solution via a series of wells into the mineralized horizons. The acid solution reacts with the colemanite forming a pregnant leach solution (PLS) containing boric acid (H₃BO₃). There are various ways of developing the well field for in-situ leaching, including “push-pull” where wells function as both as injection and recovery well; line drive; and multiple spot patterns. In addition to the vertical wells, horizontal drilling for well development is also being evaluated as a potential option for the Project. The mine wellfield development and the pattern will ultimately depend on the hydrogeologic model and the cost benefit analysis of various patterns and options.

The leaching of the colemanite will occur via the injection of a heated HCl injection fluid into the deposit through the wells. The injection fluid will remain in the formation and extracted after sufficient contact time with the colemanite. The concentration of HCl in the injection solution is one of the key control variables for the mining process to optimize the reaction with the colemanite, while not being excessive to minimize the reaction with minor impurities such as aluminum, magnesium, iron, anhydrides, and calcite.

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PLS from the wells will be recovered and piped to the boric acid processing facility. The PLS will contain primarily boric acid and calcium chloride along with minor quantities of other chlorides such as strontium, lithium, potassium, sodium, aluminum, and magnesium. Evaporative crystallization will be used to extract the boric acid from the PLS. The crystals are dewatered and then dried to make the final boric acid product.

The database used for resource estimate includes 51 drill holes and a cumulative sampled length of 81,421.4 ft. (24,823.6 m.). The database was provided to Millcreek in a digital format and represents the Project’s exploration dataset as of (July 19, 2021). Borate is listed as weight percent (%) B₂O₃ and Li as ppm. The drilling database contains 5,775 analytical values for B₂O₃ and 5,193 analytical values for Li.

TMS developed a gridded geologic model of the Project using Vulcan^™ software. The mineralization does not correlate to lithological markers as the entire sequence is predominantly lacustrine mudstone. However, detailed examination of the analytical results reveals distinct mineralized horizons. The deposit was delineated based on these patterns of mineralization into four mineralized horizons, two non- to weakly mineralized interbeds and two non-mineralized horizons bounding the deposit. Grids represent the bounding elevation surfaces of key horizons, thicknesses, and analytical grades. Mineral horizon grids were interpolated using an Inverse Distance Squared (ID2) algorithm. Mineralization is spatially defined by a resource boundary using a distance of 150 m, from the last intersection of mineralization in a drill hole.

Variogram modelling was successful for B₂O₃ grades for three of the horizons and subsequent interpolation by ordinary kriging. ID2 interpolation was used with the uppermost mineralized horizon and for Li in all horizons using the same spatial limits established with the horizon grids.

The QP has conducted an audit of the gridded model prepared by TMS. The QP loaded the resource database and grids provided by TMS into Carlson Mining^®, a geology and mine planning software that competes directly with Vulcan. The audit and validation of the gridded model consisted of the following steps: 1) Comparison of drill hole postings for intercepts and composite grades with corresponding grid values; 2) Swath plots comparing kriging to nearest neighbor searches to evaluate grade distribution and bias; and 3) the QP completed a separate estimate in Carlson Mining following the parameters used by TM to the defined resource boundary. This separate resource estimate was within 3.6% of the TMS estimate.

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Results of the mineral resource estimation are shown in Table 1.1. The resource estimate contains a combined 97.55 million tonnes (Mt) of Measured plus Indicated resources with an average grade of 6.53% B₂O₃ and 324 ppm Li, using a 5% cut-off grade for B₂O₃. The mineral resource estimate also identifies 11.43 Mt of Inferred resources under mineral control by FCCC. Approximately 91.21 Mt or 94% of the mineral resources controlled by FCCC occurs within the approved Operating Permit region approved for commercial-scale operations which was awarded to FCCC in 1995. The resource boundary also contains 23.18 Mt of Uncontrolled Resources, resources APBL does not have mineral rights to exploit.

The accuracy of resource and reserve estimates is, in part, a function of the quality and quantity of available data and of engineering and geological interpretation and judgment. Given the data available at the time this report was prepared, the estimates presented herein are considered reasonable. However, they should be accepted with the understanding that additional data and analysis available subsequent to the date of the estimates may necessitate revision. These revisions may be material. There is no guarantee that all or any part of the estimated resources or reserves will be recoverable.

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Table 1.1 Fort Cady Project Mineral Resource Estimate, October 15, 2021


Measured Resource	Horizon	Tonnage (Mt)		B₂O₃ (wt. %)		H₃BO₃ (wt. %)		Lithium (ppm)		B₂O₃ (Mt)		H₃BO₃ (Mt)
FCCC Fee Lands	UMH		0.03		5.73		10.17		259		0.00		0.00
FCCC Fee Lands	MMH		7.01		6.31		11.20		317		0.44		0.79
FCCC Fee Lands - Transmission Corridor	MMH		5.24		6.51		11.55		293		0.34		0.61
FCCC-Elementis Leased Lands	UMH		0.75		6.64		11.79		264		0.05		0.09
	MMH		18.59		6.74		11.98		349		1.25		2.23
	IMH		4.34		6.35		11.27		324		0.28		0.49
Total Measured Resource			35.96		6.57		11.67		330		2.36		4.20


Indicated Resource	Horizon	Tonnage (Mt)		B₂O₃ (wt. %)		H₃BO₃ (wt. %)		Lithium (ppm)		B₂O₃ (Mt)		H₃BO₃ (Mt)
FCCC Fee Lands	UMH		0.87		5.73		10.17		259		0.05		0.09
FCCC Fee Lands	MMH		29.00		6.47		11.50		329		1.88		3.33
FCCC Fee Lands - Transmission Corridor	MMH		20.41		6.51		11.55		293		1.33		2.36
FCCC-Elementis Leased Lands	UMH		0.31		6.68		11.87		251		0.02		0.04
	MMH		7.70		6.74		11.98		349		0.52		0.92
	IMH		3.29		6.40		11.37		324		0.21		0.37
Total Indicated Resource			61.59		6.51		11.55		318		4.01		7.12
Total Measured + Indicated Resource			97.55		6.53		11.61		324		6.37		11.31



Inferred Resource	Horizon	Tonnage (Mt)		B₂O₃ (wt. %)		H₃BO₃ (wt_. %)		Lithium (ppm)		B₂O₃ (Mt)		H₃BO₃ (Mt)
FCCC Fee Lands	UMH		0.03		5.73		10.17		259		0.00		0.00
	MMH		6.46		6.55		11.42		334		0.42		0.75
	IMH		0.59		5.64		10.01		330		0.03		0.06
FCCC Fee Lands - Transmission Corridor	MMH		1.93		6.51		11.55		293		0.13		0.22
FCCC-Elementis Leased Lands	MMH		0.27		6.74		11.98		349		0.02		0.03
FCCC-Elementis Leased Lands	IMH		2.14		6.32		10.48		330		0.14		0.24
Total Inferred Resource			11.43		6.40		11.37		324		0.74		1.31

*	Using a 5% B₂O₃ cut-off grade.

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APBL currently recognizes four primary products that can be recovered from ISL at Fort Cady Deposit: 1) boric acid and other boron compounds; 2) lithium carbonate, 3) sulfate of potash (SOP); and 4) gypsum. At the present time engineering and design for the SSBF has not included a recovery process for lithium and will likely be addressed once recovery of boric acid is operational. APBL has done some preliminary work to recover SOP, but a determination has not been made whether SOP production will be included with initial production of boric acid. Previous process design work has included using the Mannheim process to produce SOP from muriate of potash (MOP) as a method of acid regeneration for ISL. Gypsum is a byproduct of boric acid processing during regeneration of hydrochloric acid via reaction of calcium chloride with sulfuric acid.

The global boron market is currently estimated to be valued at US$ 3.2 billion at approximately 4.5Mtpa. Borates demand growth has had reasonably consistent compound annual growth rate (CAGR) at circa 4% from 2013 through 2020. Traditional demand growth coupled with new applications are forecasted to increase demand growth to circa 6% CAGR from 2021 through 2028.

Traditional applications for boron include glass manufacturing (borosilicate glass and textile fiberglass), insulation, ceramics, specialty fertilizers and biocides for the agricultural industry, detergents, fire retardants, and wood preservatives. New applications include permanent magnets for electrical vehicles, rechargeable batteries, and electronics.

The global boron market is dominated by two companies: Eti Maden (Turkish Government-Owned); and Rio Tinto Borates (a subsidiary of Rio Tinto). Together, they supply approximately 80% of global boron market. Eti Maden alone supplies over 60% of the world market. Eti Maden appears to be the only producer with meaningful additional supply capacity. Production from Rio Tinto Borates decreased 7.7% in 2020 and is forecasted to decline 4.0% in 2021. Rio Tinto Borates supplies approximately 70% of the US boron demand and this reduction in supply is resulting in higher prices and supply shortfalls. The US market is APBL’s target market.

In 2020, Rio Tinto received an average price of US$750/ton on a boric acid equivalent basis. Eti Maden average boric acid pricing is US$815/ton in 2021 and has recently announced price increases of between 3% and 4%. Since 2016, price for boric acid has steadily increased from US$767/ton to US$830/ton in 2021 (Figure 1.1). Actual prices for boric acid are typically negotiated on short-term & long-term contracts between buyers and sellers.

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Figure 1.1 Boron Pricing

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Global end-use markets for Li are estimated as follows: batteries, 65%; ceramics and glass, 18%; lubricating greases, 5%; polymer production, 3%; continuous casting mold flux powders, 3%; air treatment, 1%; and other uses, 5%. Lithium consumption significantly increased between 2014 and 2017 due to a strong demand for rechargeable lithium batteries used extensively in portable electronic devices, electric tools, electric vehicles, and grid storage applications.

At the start of 2021, Lithium Carbonate (Li₂CO₃) spot prices were at US$4,786 and steadily increased to US$13,815 in July. At the end of July 2021 Lithium Carbonate prices sharply increased with an average spot price for October 2021 at US$25,396 and that has peaked as high as US$28,688. Figure 1.2 shows annual lithium prices for the past six years.

Figure 1.2 Lithium Pricing

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Since 2017 MOP prices have fluctuated from US$276 to US$294 per ton with the exception of 2020 when the average price dipped to US$227/ton. 2020 prices most likely reflect market changes from the COVID-19 pandemic (Figure 1.3). SOP prices generally follow the same trend as MOP though at a premium. SOP prices have generally been in the US$700/ton since 2017. A factor that may affect potash pricing in the near term are the recent economic sanctions imposed on Belarus by the U.S and western Europe.

Figure 1.3 MOP and SOP Pricing

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Gypsum prices have fluctuated from US$33/ton in 2018 to US$40/ton in 2021 (Figure 1.4). 2021 prices reflect an increase of 11% from 2020. Demand for gypsum depends principally on construction industry activity. In recent years mined crude gypsum has competed with synthetic gypsum produced from flash generated from coal-fired generating stations. Synthetic gypsum production, however, is decreasing as more coal-fired stations are shut down or retired in favor of natural gas and renewable energy sources.

Figure 1.4 Gypsum Pricing

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FCCC currently has the following permits in place:

Air Permit for all processes currently identified up to 270,000 tons per year (tpy) Boric Acid and 80,000 tpy SOP.

Water Quality Permit includes all surface impoundments associated with the boric acid pilot plant and requires post mining rinsing and monitoring. FCCC remains compliant with the permit by sampling water well DHB-1 quarterly and submitting quarterly reports

Stormwater - The project has received a Notice of Non-applicability (NONA), documenting that the project does not require a stormwater permit.

Mining and Reclamation Permit issued in 1994 and was amended and the permit modified in 2019.

The BLM issued a Record of Decision (ROD) in 1994 and approved the EIS/EIR boundary. The ROD authorizes mining borates at a rate of 90,000 tpy.

The Underground Injection Control (UIC) permit administered by the U.S. Environmental Protection Agency (EPA). FCCC is currently modifying this permit and adding additional monitor wells that demonstrate that U.S. drinking water aquifers (USDW) are not degraded by ISL activities.

Additional permitting that will likely be required for the project includes:

A financial assurance cost estimate, a surface disturbance bond, will need to be updated for all new equipment, buildings, and ground disturbance.

Filing and identification of the chemical inventory, filed online.

An EPA ID will be requested when waste streams have been finalized.

FCCC will need to obtain building permits from San Bernardino County prior to construction.

Regulation S-K 1300 requires a current economic assessment to be completed which provides a reasonable basis for establishing the prospects of economic extraction of the mineral resource estimation. Key assumptions used in the economic assessment include; ISL mining operation delivering 5% boric acid in solution to an above ground processing plant; operating costs of $587 per tonne of boric acid produced; 92% conversion of boric acid in solution to saleable boric acid powder (recovery rate); 80% recovery of in-situ boron (extraction ratio) and an average sales price of US$900 per tonne of boric acid. A high-level financial model using a discount rate of 8% delivered a positive net present value to support the cut-off grade and more broadly the resulting mineral resource estimation. Potential by-product production of lithium, SOP and gypsum has been excluded from the financial model and may ultimately provide the potential for a reduction in the cut-off grade.

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Exploration to date, has focused on an approximate 1,000 acres located in the east-central portion of FCCC’s mineral holding. Future exploration efforts should address mineral potential across other portions of the Project area. In particular, the QP believes there is potential upside to conducting additional drilling to the southeast in Section 36, along trend with resources identified in this report.

The QP makes the following recommendations to advance the geology and resource characteristics for the Project that includes: 1) Additional delineation drilling of 15 drill holes to further refine resource classification and to further test resource potential on the southern land holdings held by APBL; 2) standardizing sample lengths in future drilling to reduce sampling an analytical costs; 3) Mineralogical testing to identify the source of Li mineralization along with testing of PLS to help determine recovery and what processes might be required to extract Li and steps to produce lithium carbonate LiCO₃ and/or lithium hydroxide (LiOH.(H₂O)n); 4) consider using seismic and electromagnetic surveying to assist in understanding structural setting a facies in the project area; and 5) further analysis should be completed to determine if economics will support a lower cut-off grade for B₂O₃.

The QP concludes that there are reasonable prospects for economic extraction for the mineral resource estimated and presented in this Initial Assessment.

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2	INTRODUCTION

American Pacific Borates Limited (APBL) Is a publicly traded company listed on the Australian Securities Exchange under the symbol ABR. Through its wholly owned U.S. subsidiary, Fort Cady (California) Corporation (FCCC), the company is developing the Fort Cady Borate Project (Project). The Project contains the largest known global deposit of colemanite, not owned by the Turkish Government controlled entity, Eti Maden. Colemanite is a hydrated calcium borate mineral (2CaO • 3B₂O₃ • 5H₂O) found in evaporite deposits. The region surrounding the Project has a long history of borate mining including Boron, Calico Mountain, Searles Lake, and Lila C Mine. Through in-situ leaching (ISL), FCCC will recover borates (boron-oxygen compounds), boric acid (H₃BO₃), Li, and other potential commodities.

Millcreek Mining Group (Millcreek) has prepared this Assessment Report on the Project to evaluate the resources and development activities performed by FCCC to advance this project to a viable ISL operation. This report has been prepared under the S-K 1300 rules and guidelines of the U.S. Securities and Exchange Commission (SEC) and will be used in supporting a listing on the NASDAQ stock exchange, under the name ‘5E Advanced Materials, Inc.’. The Qualified Person (QP) for this report is Mr. Steven Kerr, CPG. Mr. Kerr is the Principal Consultant – Geology at Millcreek, with over 36 years experience in exploration and resource evaluation. Mr. Kerr is a Certified Professional Geologist with the American Institute of Professional Geologists (CPG-10352), a recognized professional organization of the Committee for Mineral Reserves International Reporting Standards (CRIRSCO).

This Assessment Report primarily utilizes data collected on the Project by Millcreek from FCCC and on interviews, work sessions, and meetings at their offices in Hesperia, California. Some publicly available data and information has been used as well in the preparation of this Assessment Report, but this data and information are regional in nature, not specific to the Fort Cady Borate Deposit. The QP conducted a site visit to the Project on July 20 and 21, 2021. During the site visit, the QP toured the property, observed drilling operations for a water monitor well program, met with mine personnel, and examined the core from several of the exploration holes completed in 2017.

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The effective date of this report is considered October 15, 2021. With reference to this report, the “Effective Date” means the date of the most recent scientific or technical information included in the Assessment Report.

Soon after acquiring the Fort Cady Borate Project in 2017, APBL completed an exploration drilling program to validate previous exploration efforts and expand mineral resources. Following the drilling program, a JORC mineral resource estimate was prepared by Terra Modelling Services (TMS) for the Project (December 2017). TMS later updated the JORC mineral resource estimate in December 2018.

In 2018, the Initial Study of the Project was completed by APBL and reviewed by RESPEC Company LLC (RESPEC). The Project contemplated a three phase Project which, in full production, would produce 450 kstpa boric acid (BA) and 120 kstpa sulfate of potash (SOP). APBL subsequently modified the Project in January 2019 by allowing for a low capex starter project, that split the first phase, Phase 1 into Phase 1A and Phase 1B, which provided a lower upfront capital requirement to assist financing flexibility.

Based on further engineering work, a Second Study was released in February 2021, making a substantial increase in proposed SOP production, and increasing BA production by 50% in Phase 1A. A third subphase, Phase 1C was added to decouple BA and SOP production in Phase 1B resulting in:

•

Phase 1A targeting production of 20 kstpa of SOP (K₂SO₄) and 9 kstpa of BA (H₃BO₃)

•

Phase 1B targeting SOP production at a rate of 60 kstpa

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Phase 1C targeting BA production at a rate of 81 kstpa.

In June 2020, APBL secured financing of A$77M to fully finance Phase 1A and was subsequently awarded its final operational permit in August 2020.

In May 2021, APBL announced the deferral of the approach that saw Phase 1 delivered in three sections. It is now focused on delivering Phase 1 in its entirety. It is also considering an option that brings forward the construction of Phase 2. The two base case mine options under consideration are:

•

Option 1 – Combining all planned Phase 1 operations into a 90 kstpa BA and 80kstpa SOP operation; and

•

Option 2 – Larger operation combining option 1 above with planned Phase 2 operation to deliver 270 kstpa BA and 240 kstpa SOP operation.

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APBL continues to make further refinements with the Project progressing towards development and production. APBL has retained Agapito Associates (Agapito) to perform additional dissolution tests on the injection solution that will further test acid concentration and whether further enhancements can be gained with elevated temperatures, pressures, and with adding varying amounts of calcium chloride (CaCl₂) to retard calcite dissolution in favor of borate dissolution. Results of dissolution testing will provide input to a wellfield design study by Agapito. APBL has also initiated engineering and design for a small-scale boron facility (SSBF). Once the SSBF is operational, it will provide refined inputs for capital and operational expenditures.

This report presents the resources at the Fort Cady Borate Project. Reserves are not presented in this report since new dissolution tests are ongoing and SSBF work is proceeding, both of which provide key inputs to the economic recoverability of the resources.

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3	PROPERTY DESCRIPTION

The Project is located in the Mojave Desert region in eastern San Bernardino County, California. The project lies approximately 118 mi. northeast of Los Angeles near the town of Newberry Springs and is approximately 36 mi. east of the city of Barstow (Figure 3.1). Central location for the project area is N34°45’25.20”, W116°25’02.02”. Fort Cady resides in a highly prospective area for borate and Li mineralization, and the deposit is situated in the Hector evaporite basin within close proximity to the Elementis Specialties PLC (“Elementis”) Hectorite mine. The Project has a similar geological setting as Rio Tinto Borates’ Boron operations and Nirma Limited’s Searles Lake (Trona) operations, situated approximately 75 mi. west-northwest and 90 mi. northwest of the Project, respectively.

Figure 3.1 General Location Map

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3.1

MINERAL TENURE

Mineral tenure for the Project is through a combination of federal mining claims, a mineral lease, and private fee simple lands. These include 1,010 acres of fee simple patented or privately held land; 2,380 acres of unpatented claims held by FCCC; and 1,520 acres of unpatented claims leased by FCCC from Elementis. Mineral holdings occupy portions of sections 22, 23, 24, 25, 26, 27, and 36, Township 8 North, Range 5 East, San Bernardino Meridian (SBM) and section 19, 20, 29, 30, and 31, Township 8 North, Range 6 East, SBM.

Other areas surrounding the project area include patented and unpatented lands of the Elementis Hectorite Mine directly west of the Project and unclaimed public lands managed by the U.S. Department of Interior, Bureau of Land Management (BLM) to the north and east. Land south of the project area are part of the U.S. Marine Corps Twentynine Palms Base. Figure 3.2 shows the mineral tenure for the project.

FCCC owns two parcels of fee simple lands in Sections 25 and 36, Township 8 North, Range 5 East, SBM. An electrical transmission corridor operated by Southern California Edison (SCE) tracts northeastward through the fee lands with SCE having surface and subsurface control to a depth of 500 ft. and affecting approximately 91 acres of land owned by FCCC. While this limits access to the land, mineralization occurs at depths in excess of 1,000 ft. which is still accessible to solution mining.

FCCC currently holds two unpatented lode 117 unpatented placer claims. Both lode claims were originally filed by Duval in 1978. Placer claims were filed between October 29, 2016, and February 24, 2017. A review of the BLM MLRS database shows claim status as filed with next assessment fees due 9/1/2022.

FCCC entered into a Mineral Lease Agreement with Elementis Specialties, Inc. to examine the mineral potential and develop commercial mining operations for a group of mining claims that are adjacent to the Hectorite Mine. The lease covers 36 unpatented placer claims, 15 unpatented lode claims, a diagonal swath of two unpatented placer claims, and excludes any and all patented claims. The lease carries a 3% royalty on net returns from all ores, minerals, or other products produced from the leased lands. The lease became effective on October 1, 2011, with a duration of 10 years with certain provisions to extend the lease. FCCC and Elementis executed a lease extension to the duration to July 1, 2022, while the parties continue to negotiate terms and conditions for a new mining lease.

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Lastly, the State of California owns approximately 272 acres of land in Section 36, Township 8 North, Range 5 East, SBM. This land is potentially available to FCCC through a mineral lease from the California State Lands Commission.

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4	ACCESSIBILITY, CLIMATE, LOCAL RESOURCES, INFRASTRUCTURE AND PHYSIOGRAPHY

The Project is located in the western Mojave Desert with arid, hot, dry, and sunny summers of low humidity and temperate winters. Based on climate data from the nearby town of Newberry Springs, the climate over the past 30 years indicates average monthly high temperatures ranging from 55°F in December to 98.2°F in July. Monthly low temperatures range from 40.1° in December to 74.3° in August. Extremes range from a record low of 7°F to a record high of 117°F. Maximum temperatures in summer frequently exceed 100°F while cold spells in winter with temperatures below 20°F occur from time to time but seldom last for more than a few days. Average rainfall is generally less than 10 inches per year with most precipitation occurring in the winter and spring.

The project area is located on a gentle pediment with elevation ranging from approximately 1,970 ft. to approximately 2,185 ft. above sea level. Basalt lava flows cover most of the higher elevations or hilltops with flat ground and drainages covered in pale, gray-brown, silty soils. Basalt lava flows become more dominant south of the project area with the Lava Bed Mountains located a few miles south of the Project area. The Project area’s vegetation is dominated by burro weed, creosote, cactus, and scattered grasses.

The BNSF Railroad main line from Las Vegas to Los Angeles runs subparallel to I-40. A rail loadout is located approximately 1.2 mi. north of the National Trails Highway on a road that bears north and located 0.4 mi. west of CR20796. San Bernardino County operates six general aviation airports with the closest airport to the project being the Barstow-Daggett Airport located approximately 23 mi. west of the Project on the National Trails Highway. Commercial flight service is available through five airports in the greater Los Angeles area and in Los Vegas, NV. A dedicated cargo service airport is located approximately 65 mi. southwest of the Project.

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Construction of an ISL mining operation and processing plant at the Project will require local resources of contractors, construction materials, energy resources, employees, and housing for employees. The Project has good access to I-40 which connects it to numerous sizable communities between Barstow and the greater Los Angeles area offering excellent access to transportation, construction materials, labor, and housing. The Project currently has limited electrical service that is sufficient for mine office and storage facilities on site but will require an upgrade for plant and wellfield facilities. FCCC is currently exploring options for upgrading electrical services to the Project. An electrical transmission corridor operated by Southern California Edison extends northeastward through the eastern part of the project. The project has two water wells located nearby to support ISL operations. Currently no natural gas connects to the project, but FCCC is negotiating services with two suppliers in the region with a gas transmission pipeline located proximal to the Project.

The plant site currently has a 1,600 ft² mine office building, storage buildings, a prepared level pad for the SSBF (20 acres), and a gypsum storage area occupying 17 acres. Gypsum is a byproduct of past pilot plant production and may be a future byproduct that can be sold to the regional market.

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5	HISTORY

Several borate-bearing deposits are known in the region, including Calico Mountain, Boron, and Searles Lake. Discovery of the Fort Cady borate deposit occurred in 1964 when Congdon and Carey Minerals Exploration Company found several zones of colemanite, a calcium borate mineral, between the depths of 405m to 497m (1,330 ft. to 1,570 ft.) below ground surface in Section 26, TSN, R5E (Simon Hydro-Search, 1993).

In September 1977, Duval Corporation (“Duval”) initiated land acquisition and exploration activities near Hector, California, and by March 1981, completed 33 exploration holes. In 1981, Duval began considering conventional underground extraction of the ore body. Because of the depth, conventional underground mining was determined not to be economically feasible and subsequent studies and tests performed by Duval indicated that in-situ mining technology was feasible (Simon Hydro-Search, 1993).

Duval commenced limited-scale solution mining in June 1981 and an additional 17 production wells were completed between 1981 and 2001 which were used for injection testing and pilot-scale operations. In July 1986, a series of tests were conducted by Mountain States Mineral Enterprises Inc. (FCMC) In these tests, a dilute hydrochloric acid solution was injected through a well into the ore body and a boron-rich solution was withdrawn from the same well. In July 1986, FCMC became involved with the project with the view of commencing pilot-scale testing. The first phase of pilot plant operations was conducted between 1987 and 1988. Approximately 500 tonnes of boric acid were produced during this time. Given the promising results of the pilot-scale tests the project was viewed to be commercially viable (Dames & Moore, 1993) and concentrated permitting efforts for commercial-scale operations began in early 1990. Final approval for commercial-scale solution mining and processing was attained in 1994.

Extensive feasibility studies, detailed engineering and test works were subsequently undertaken in the late 1990’s and early 2000’s. This included a second phase of pilot plant operations between 1996 and 2001 during which approximately 2,000 tonnes of a synthetic colemanite product (marketed as CadyCal 100) were produced. Commercial-scale operations were not commissioned due to low product prices and other priorities of the controlling entity.

Production data for these projects were recently obtained by FCCC and a summary of this data is provided in Tables 5.1 through 5.4. Little other information is available for these tests, and the results could not be independently verified. These results should be considered historical in nature.

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Table 5.1 Duval Testing Results


Test No.	Volume Injected (Gal)		Injection Rate (Gal/min)		Pump Pressure (PSI)		Acid (%)		Volume Recovered (Gal)		Recovery Rate (Gal/min)		Average Concentration HBO₃ (%)		Maximum Concentration HBO₃ (%)
1		680		1.5		150		16% HCl		700		1.0-2.0		0.3
		1,500		2.0		275		5% H₂SO₄		1,500		1.0-2.0		0.5		1.5
		1,400		1.5-2.0		150		5% H₂SO₄		2,000		1.0-2.0		1.5		4.6
		1,500		2.0		275		23% H₂SO₄		1,500		1.0-2.0		1.0		4.0
2		2,250		2.0		300		8% H₂SO₄		2,000		1.5-2.0		1.5		4.0
3		5,358		2-2.5		275		6.9% H₂SO₄				1.0-1.5		3.0		6.9
3		6,597		2-2.5		275		17.5% HCl		28,927				3.0		6.9
4		19,311		2-2.5		230-275		6.2% HCl & 2.4% H₂SO₄		67,995		1.0-1.5		3.0		6.5
5		20,615		2.0		290		16% HCL		112,637		1.0-1.5		2.5		5.2
6		21,569		20.0		275		1.6% HCl		63,460		1.0-1.5		1.1		1.7

Table 5.2 Mountain States Testing Injection Summary


Date					Gallons				Pounds		Theoretical HBO₃
Series	From	To	Test Nos.	Wells (SMT)	Series		Cumulative		HCl		CO₂		Series		Cumulative
1	8/4/1986	8/23/1986	1 - 3	6 & 9		67,972		67,972		23,286				59,540		59,540
2	11/4/1986	11/10/1986	4 - 7	6		45,489		113,461		15,500				39,431		98,971
3	12/9/1986	12/18/1986	8 -11	6		53,023		166,484		15,398				39,173		138,144
4	6/18/1986	6/27/1987	12 -15	9		47,640		214,124				4,313		18,184		156,328
Total						214,124		214,124		54,184		4,313		156,328		156,328

Table 5.3 Mountain States Testing Recovery Summary


Date					Gallons				Pounds BA				% BA in Solution, by Surge Tank						Theoretical BA
Series	From	To	Test Nos.	Wells (SMT)	Series		Cumulative		Series		Cumulative		High		End		Average		Series		Cumulative
1	8/7/1986	10/17/1986	1 - 3	6 & 9		128,438		128,438		32,608		32,608		3.84		1.56		2.5		54.77		54.77
2	11/5/1986	11/13/1986	4 - 7	6		51,636		180,074		21,223		53,831		5.74		4.05		4.68		53.83		54.39
3	12/10/1986	1/13/1987	8 -11	6		99,889		279,963		33,386		87,217		5.59		1.93		4.18		85.23		63.14
4	6/9/1987	7/0/1987	12 -15	9		86,595		366,558		18,973		106,190		3.55		1.81		2.6		104.34		67.93
Total						366,558		366,558		106,190		106,190						3.79				67.93

Over US$80 million has been spent on the Fort Cady Project, including license acquisition, drilling, mineral resource estimation, well testing, metallurgical testing, feasibility studies and pilot plant test work. In addition, the Project has previously obtained all operating and environmental permits required for commercial solution mining operations to produce 90,000 short tons per annum of boric acid.

In May 2017, FCCC’s parent company, APBL executed a Share Purchase Agreement with the project vendors (Atlas Precious Metals Inc.) to purchase 100% of the Project and listed APBL on the Australian Securities Exchange (ASX) by way of an Initial Public Offering (IPO). The IPO was completed in July 2017.

Soon after acquiring the Fort Cady Borate Project, FCCC completed an exploration drilling program to validate previous exploration efforts and expand mineral resources. Following the drilling program, a JORC mineral resource estimate was prepared by Terra Modelling Services (TMS) for the Project (February 1, 2018). TMS later updated the JORC mineral resource estimate in December 2018. The 2018 JORC mineral resource estimate identified 38.87 million tonnes (Mt) of measured resources, 19.72 Mt of indicated resources, and 61.85 Mt of inferred resources using a B2O3 cut-off grade of 5%.

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Table 5.4 Fort Cady Mineral Corporation Production Summary


Date	Total Minutes		Flow to Plant				pH		Free Acid (g/l)		Boric Acid (%)		Chloride (g/l)		Sulfate (g/l)		Boric Acid (tons**)		B2O3 (tons)**		CadyCal 100* (tons)**
Date	Total Minutes		Gallons		Gal/min		pH		Free Acid (g/l)		Boric Acid (%)		Chloride (g/l)		Sulfate (g/l)		Boric Acid (tons**)		B2O3 (tons)**		CadyCal 100* (tons)**
Jan-01		7,215		258,556		35.80		5.83				2.33		12.54		3.76		15		9		20
Feb-01		7,785		331,886		42.60		2.54		0.35		2.36		12.13		4.94		25		14		33
Mar-01		10,470		422,922		40.40		2.41		0.23		1.90		15.84		3.23		34		19		45
Apr-01		10,290		393,824		38.30		1.86		2.60		5.43		42.11		8.18		41		23		53
May-01		7,560		296,000		39.20		2.02		2.67		5.77		44.77		8.70		31		17		40
Jun-01		3,375		120,928		35.80		0.67		1.35		3.12		27.84		5.30		12		7		16
Jul-01		2,385		77,157		32.40		1.19		0.31		2.00		12.74		2.60		7		4		9
Aug-01		3,300		142,207		43.10		4.04		0.07		3.84		19.60		3.08		15		8		19
Sep-01		4,875		247,901		50.90		2.77		0.12		3.44		23.21		3.68		21		12		28
Oct-01		10,035		478,723		47.70		2.03		0.35		3.00		15.54		4.60		37		1		49
Nov-01		9,270		371,171		40.00		1.99		0.16		2.39		14.15		4.02		23		13		30
Dec-01		12,525		353,885		28.30		1.83		0.17		2.52		14.94		2.58		29		16		38
01-Total		89,085		3,495,160		39.20		2.44		0.73		3.19		21.37		4.74		291		164		381
00-Total		87,255		3,142,413		36.00		2.14		0.25		2.70		12.42		2.54		279		157		366
99-Total		92,820		2,475,770		26.70		1.59		0.48		2.82		10.13		6.84		201		113		263
98-Total		111,468		2,715,319		24.40		1.24		0.91		2.85		7.78		10.19		217		122		284
97-Total		109,040		2,692,940		24.70		0.99		1.84		3.10		3.52		13.00		252		142		329
96-Total		101,212		2,711,044		26.80		1.33		1.32		3.01		2.96		5.76		244		137		319

In 2018, the Initial Study for the Project was completed by RESPEC for APBL. At the time, the Project contemplated a three-phase project which, in full production, would produce 450 kstpa BA and 120 kstpa sulfate of potash. APBL subsequently modified the Project in January 2019 by allowing for a low capex starter project, that split the first phase, Phase 1 into Phase 1A and Phase 1B, which provided a lower upfront capital requirement to assist financing flexibility.

Based on further engineering work, the Second Study was released in February 2021, making a substantial increase in proposed SOP production, and increasing BA production by 50% in Phase 1A. and a third subphase, Phase 1C was added to decouple BA and SOP production in Phase 1B resulting in:

•

Phase 1A targeting production of 20kstpa of SOP (K₂SO₄) and 9kstpa of BA (H₃BO₃)

•

Phase 1B targeting SOP production at a rate of 60 kstpa

•

Phase 1C targeting BA production at a rate of 81 kstpa.

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In June 2020, APBL secured financing of A$77M to fully finance Phase 1A and was subsequently awarded its final operational permit in August 2020.

In May 2021, APBL announced the deferral of the approach that saw Phase 1 delivered in three sections and the company is now focused on delivering Phase 1 in its entirety. The company is also considering an option that brings forward the construction of Phase 2. The two base case mine options under consideration are:

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Option 1 – Combining all planned Phase 1 operations into a 90 kstpa boric acid and 80 kstpa SOP operation; and

•

Option 2 – Larger operation combining option 1 above with planned Phase 2 operation to deliver 270 kstpa boric acid and 240 kstpa SOP operation.

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6	GEOLOGICAL SETTING, MINERALIZATION AND DEPOSIT

6.1

REGIONAL SETTING

The Project area is located in the western Mojave Desert and is part of the Basin and Range Physiographic Province. The region is characterized by narrow faulted mountain ranges and flat valleys and basins, the result of tectonic extension that began approximate 17 million years ago. The Project lies within the Hector Basin of the Barstow Trough and is bounded on the southwest by the San Andreas fault zone and the Transverse Ranges, on the north by the Garlock fault zone, and on the east by the Death Valley and Granite Mountain faults. Numerous faults of various orientations are found within the area with various orientations though the predominant trend is to the northwest.

The Barstow Trough, which is a structural depression, extends northwesterly from Barstow toward Randsburg and in an east-southeast trend toward Bristol. It is characterized by thick successions of Cenozoic sediments, including borate-bearing lacustrine deposits, with abundant volcanism along the trough flanks. The northwest-southeast trending trough initially formed during Oligocene through Miocene times. As the basin was filled with sediments and the adjacent highland areas were reduced by erosion, the areas receiving sediments expanded, and playa lakes, characterized by fine-grained clastic and evaporitic chemical deposition, formed in the low areas at the center of the basins.

Exposures of fine-grained lacustrine sediments and tuffs, possibly Pliocene in age, are found throughout the project area. Younger alluvium occurs in washes and overlying the older lacustrine sediments. Much of the project area is covered by Recent olivine basalt flows from Pisgah Crater, which is located approximately two mi. east of the site (Figures 6.1 and 6.2). Thick fine-grained, predominantly lacustrine mudstones appear to have been uplifted, forming a block of lacustrine sediments interpreted to be floored by an andesitic lava flow.

Figure 6.1 Surface Geology in the Newberry Springs Area

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There are three prominent geologic features in the project area:

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Pisgah Fault, which transects the southwest portion of the project area west of the ore body.

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Pisgah Crater lava flow located 3.2 km east of the site: and

•

Fault B, an unnamed fault, located east of the deposit.

The Pisgah Fault is a right-lateral slip fault that exhibits at least 200 m. of vertical separation in the project area. The east side of the fault is up thrown relative to the west side. Fault B is located east of the ore body and also exhibits at least 200 m. of vertical separation. The borate ore body is situated within a thick area of fine-grained, predominantly lacustrine (lakebed) mudstones, east of the Pisgah Fault and west of Fault B. The central project area has been uplifted along both faults, forming an uplifted block. Test borings emplaced through the ore body reportedly show the presence of claystone at the base and around the evaporite/mudstone ore body. Exploration drilling in the project area indicate that the deposit lies between approximately 400 m. and 550 m. below ground level. The ore body consists of variable amounts of calcium borate (colemanite) within a mudstone matrix (Simon Hydro-Search, 1993).

6.2

MINERALIZATION

Mineralization occurs in the subsurface in a sequence of lacustrine sediments ranging in depths from 1,135 to 1,872 ft. below the surface. The mineralization is hosted by a sequence of mudstones and tuffs, consisting of variable amounts of colemanite, a calcium borate (2CaO • 3B₂O₃ • 5H₂O). Colemanite is the target mineral for this deposit and is found in evaporite deposits of alkaline lacustrine environments. Colemanite is a secondary alteration mineral formed from borax and ulexite. The colemanite is associated with thinly laminated siltstone, clay and gypsum beds containing an average of 9% calcite, 35% anhydrite plus 10% celestite (SrSO₄) (Wilkinson & Krier, 1985). In addition to colemanite and celestite, elevated levels of Li have been found through chemical analyses of drill samples.

X-ray diffraction (XRD) analysis of core samples from the deposit indicate the presence of the evaporite minerals anhydrite, colemanite, celestite, and calcite. The mineralogy of the detrital sediments include quartz, illite, feldspars, and clinoptilolite, a zeolite. The deposit underlies massive clay beds which appear to encapsulate the evaporite ore body on all sides as well as above and below the deposit. This enclosed setting makes the deposit an ideal candidate for in-situ mining technology affording excellent containment of the leachate solution.

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6.3

MINERAL DEPOSIT

The eastern margin of mineralization appears to be roughly linear, paralleling the Pisgah Fault which lies approximately 1 mi. to the west (Figures 6.3 and 6.4). This boundary was considered by Duval geologists to be controlled by a facies change from evaporite rich mudstones to carbonate-rich lake beds, as a result of syn-depositional faulting. The northeast and northwest boundaries of the deposit are controlled by facies changes to more clastic material, reducing both the overall evaporite content and the concentration of colemanite within the evaporites. The southeast end of the deposit is open-ended and additional drilling is necessary to define the southeastern limits of borate deposition (Wilkinson & Krier, 1985).

Drilling of the deposit by Duval Corp. in the late 1970’s and early 1980’s has defined the following lithological sequence (Figure 6.5). Four major units have been identified:

Unit 1: is characterized by a 490 to 655 ft thick sequence of red-brown mudstones with minor sandstone, zeolitized tuff, limestone, and rarely hectorite clay beds. Unit 1 is intersected immediately below the alluvium and surface basaltic lavas.

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Unit 2: is a green-grey mudstone that contains minor anhydrite, limestone, and zeolitized tuffs. Unit 2 has a thickness ranging from 330 to 490 ft. and is interpreted as lacustrine beds.

Unit 3: is a 245-to-490-foot thick evaporite section which consists of rhythmic laminations of anhydrite, clay, calcite, and gypsum. Unit 3 contains the colemanite mineralization. Thin beds of air fall tuff are found in the unit which provide time continuous markers for interpretation of the sedimentation history. These tuffs have variably been altered to zeolites or clays. Anhydrite is the dominant evaporite mineral, and the ore deposit itself is made up mostly of an intergrowth of anhydrite, colemanite, celestite, and calcite with minor amounts of gypsum and howlite.

Unit 4: is characterized by clastic sediments made up of red and grey-green mudstones and siltstones, with locally abundant anhydrite and limestone. The unit is approximately 160 ft. thick and rests directly on an irregular surface of andesitic lava flows. Where drilling has intersected this boundary, it has been noted that an intervening sandstone or conglomerate composed mostly of coarse volcanic debris is usually present.

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7	EXPLORATION

7.1

HISTORIC DRILLING

Duval completed 35 drill holes (DHB Series) between 1979 and 1981 as part of their exploration efforts. With the exception on one hole, holes were drilled using a combination of rotary drilling through the overburden followed by core drilling through the evaporite sequence. DHB-32 was drilled as a water well southeast of the Project. Geologic logs of rotary cuttings and core were completed for all holes followed by geochemical analyses of the core. Duvall paid particular attention in logging to identifying marker beds (ash tuffs) for correlation. In addition to geologic logging, down-hole geophysics were completed on 25 holes for gamma ray and neutron. A few holes had additional geophysical logs completed for compensated density, deviation, induction, elastic properties, and caliper.

In 1981 and 1982, Duval drilled five wells to be used in injection/recovery tests (SMT Holes). Like previous drilling, the wells were rotary drilled through the overburden and cored through the evaporite sequence. Following coring, 5.5-inch casing was set through the cored interval. All five wells were logged, and analytical samples collected from the cored intervals are available for SMT-1, SMT-3, and SMT-3. Gamma ray and neutron logs were collected from all five wells, along with caliper, compensated density, and induction on a few of the other wells.

Duval drilled three more wells in 1992 and 1993 (SMT-92 & 93 Holes). These three wells were rotary drilled to full depth and no geologic samples were collected.

FCMC completed two drilling campaigns during their participation on the project. The P Series holes were completed between 1987 and 1996 as rotary holes for injection/recovery wells. Cuttings samples were collected for analysis on 5-foot intervals for holes P-1, P-2, and P-3. A ten-foot sampling interval was used for sampling on P-4. No geologic samples were collected for holes P-5, P-6, and P-7. FCMC completed three S Series wells in 1990. All three wells were rotary drilled and no geologic sampling was performed. FCMC completed down-hole geophysics on all the P and S-series wells. Historic drilling completed by Duvall and FCMC is summarized in Table 7.1.

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Table 7.1 Historic Drilling Summary


Drill Hole ID	UTM 83-11 (m)				Collar Elev. (ft.)		Depth (ft.)		Rotary Interval (ft.)				Cored Interval (ft.)				No. of Samples
	Easting		Northing		Collar Elev. (ft.)		Depth (ft.)		From		To		From		To		No. of Samples
DHB-01		553,336		3,846,154		2,003.7		1,623		0		1,090		1,090		1,623		187
DHB-02		554,062		3,846,179		2,032.6		1,679		0		955		955		1,443
DHB-03		553,089		3,845,899		1,979.7		1,773		0		940		940		1,773		214
DHB-04		552,855		3,845,669		1,980.6		1,708		0		1,194		1,194		1,708		178
DHB-05		552,848		3,846,153		1,977.7		1,730		0		1,043		1,043		1,730		179
DHB-06		553,115		3,846,386		2,008.2		1,616		0		1,040		1,040		1,616		125
DHB-07		553,736		3,845,492		2,000.1		1,735		0		1,063		1,063		1,735		181
DHB-08		552,575		3,846,214		1,966.0		1,809		0		1,072		1,072		1,809		186
DHB-09		552,391		3,846,408		1,966.6		1,750		0		1,137		1,137		1,750		138
DHB-10		552,349		3,846,631		1,980.3		1,655		0		1,148		1,148		1,655		86
DHB-11		552,599		3,846,390		1,976.2		1,671		0		1,150		1,150		1,671		86
DHB-12		552,824		3,846,402		1,992.5		1,625		0		1,130		1,130		1,625		85
DHB-13		552,104		3,846,877		1,978.0		1,661		0		1,140		1,140		1,661		70
DHB-14		553,089		3,846,151		1,987.4		1,631		0		1,105		1,105		1,631		80
DHB-15		553,580		3,846,158		2,012.5		1,609		0		1,177		1,177		1,609		51
DHB-16		553,263		3,845,595		1,984.9		1,845		0		1,193		1,193		1,845		138
DHB-17		552,843		3,845,925		1,982.3		1,804		0		1,178		1,178		1,804		151
DHB-18		553,238		3,845,431		1,977.8		1,880		0		1,212		1,212		1,878		106
DHB-19		554,141		3,845,287		2,033.6		1,460		0		1,060		1,060		1,460		74
DHB-20		553,006		3,845,437		1,997.5		1,671		0		1,207		1,207		1,671
DHB-21		553,292		3,845,143		2,010.6		1,752		0		1,118		1,118		1,828		39
DHB-22		553,275		3,845,902		1,987.7		1,711		0		1,196		1,196		1,711		135
DHB-23		553,508		3,845,110		2,020.5		1,857		0		1,208		1,208		1,857		114
DHB-24		553,523		3,845,637		1,994.2		1,780		0		1,202		1,202		1,780		119
DHB-25		553,699		3,845,297		2,020.5		1,818		0		1,248		1,248		1,818		152
DHB-26		553,891		3,845,056		2,050.0		1,702		0		1,106		1,106		1,702		106
DHB-27		553,698		3,844,803		2,043.4		1,795		0		1,228		1,228		1,795		95
DHB-28		554,004		3,844,943		2,053.3		1,690		0		1,185		1,185		1,690		115
DHB-29		554,164		3,844,454		2,040.2		1,610		0		1,203		1,203		1,610		101
DHB-30		553,873		3,844,630		2,050.0		1,720		0		1,250		1,250		1,720		83
DHB-31		553,865		3,844,381		2,036.9		1,460		0		1,195		1,195		1,625		41
DHB-32		551,770		3,843,845		2,045.0		870		0		870
DHB-33		554,045		3,844,254		2,043.4		1,601		0		1,124		1,124		1,860		80
DHB-34		553,746		3,845,722		2,115.6		1,525		0		1,150		1,150		1,620		79
DHB-35		551,249		3,848,166		2,068.0		1,449		0		1,194		1,194		1,459
P1		553,093		3,845,908		1,984.4		1,500		0		1,500						20
P2		553,094		3,845,969		1,984.4		1,510		0		1,510						21
P3		553,033		3,845,902		1,981.1		1,510		0		1,510						18
P4		553,033		3,845,935		1,977.3		1,510		0		1,510						34
P5		553,193		3,845,874		1,985.0		1,547		0		1,547						0
P6		553,209		3,845,946		1,989.0		1,525		0		1,525						0
P7		553,217		3,846,023		1,992.0		1,475		0		1,475						0
SMT-1		553,323		3,846,144		2,004.1		1,315		0		1,235		1,235		1,315		59
SMT-2		553,310		3,846,135		2,004.1		1,679		0		1,234		1,234		1,316		55
SMT-3		553,211		3,845,897		1,987.7		1,679		0		1,325		1,325		1,518		69
SMT-6		553210		3845934		1,988.0		1,450		0		1,341		1,341		1,450		0
SMT-9		553194		3845837		1,985.0		1,497		0		1,341		1,341		1,497		0

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7.2

APBL DRILLING

Since acquisition of the Project in May 2017, APBL has completed 14 drill holes, which confirmed previous drilling results and expanded the Mineral Resource Estimate at Fort Cady. Table 7.2 provides a summary of the 2017 drilling program and Figure 7.1 shows drilling locations. A cross-section through the deposit is also displayed in 7.2. Drilling through the overburden sequence was completed using rotary air blast drilling. This was followed by drilling HQ (2.5-inch) core through the evaporite sequence. The core was logged and evaluated using industry standard techniques. All drill holes were completed vertically with no greater than five degrees of deviation.

Table 7.2 2017 APBL Drilling Summary


Drill Hole ID	UTM 83-11 (m)				Collar Elev. (ft.)		Depth (ft.)		Rotary Interval (ft.)				Cored Interval (ft.)				No. of Samples
	Easting		Northing		Collar Elev. (ft.)		Depth (ft.)		From		To		From		To		No. of Samples
17FTCBL-01		552,638		3,846,716		2006.02		1568.59		0		1204		1204		1568.59		82
17FTCBL-02		552,711		3,846,490		1996.73		1508.6		0		1208		1208		1508.6		107
17FTCBL-03		552,981		3,846,485		2019.1		1458.62		0		1153		1153		1458.62		91
17FTCBL-04		552,695		3,846,268		1977.87		1738.04		0		1266		1266		1738.04		162
17FTCBL-05		552,930		3,846,267		1995.36		1588.9		0		1237		1237		1588.9		150
17FTCBL-06		553,145		3,846,260		2001.55		1502.11		0		1189		1189		1502.11		83
17FTCBL-07		552,772		3,846,041		1977.41		1774.55		0		1196		1196		1774.55		207
17FTCBL-08		552,972		3,846,042		1983.61		1625.08		0		1202		1202		1625.08		153
17FTCBL-09		553,179		3,846,037		1992.3		1560.1		0		1169		1169		1560.1		120
17FTCBL-10		552,831		3,845,939		1989.29		1646.59		0		1208		1208		1646.59		176
17FTCBL-11		553,078		3,845,899		1983.22		1777.53		0		1332		1332		1777.53		155
17FTCBL-12		552,963		3,845,801		1973.35		1749.55		0		1281		1281		1749.55		212
17FTCBL-13		553,153		3,845,818		1992.3		1768.54		0		1313		1313		1768.54		155
17FTCBL-14		553,270		3,845,608		1986.53		1844.54		0		1328		1328		1844.54		260

Core logging was completed on all drill holes and included lithological and geotechnical logging. Downhole geophysical logs, including Gamma Ray, Induction and standard caliper were completed on all drill holes from surface to total depth (TD) with the exception of 17FTCBL009 where adverse hole conditions resulted in only partial geophysical logging. All core is logged and photographed according to industry standard procedures. An example of core photos is shown in Figure 7.3.

A geotechnical drill hole, APBL023, was also completed in 2017. This well was cored its entire length and a geologic log was completed to define mineralized horizons. No splitting or analytical samples were collected from this hole to preserve core for subsequent geotechnical testing. This hole was subsequentially used as an in-situ leaching well.

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The QP considers the drilling program by APBL to be of sufficient quality to support a Mineral Resource Estimate.

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Figure 7.2 Cross-section Through the Fort Cady Deposit

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Figure 7.3 Core Photo, 17FTCBL-014

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7.3

HYDROGEOLOGY

7.3.1

Hydrologic setting

The Fort Cady deposit is situated in the Lavic Valley Groundwater Basin, which extends for approximately 30 miles in a NNW-SSE direction and is approximately seven miles wide in the project area. The basin is bounded to the west by the Pisgah Fault, beyond which is the Lower Mojave River Valley Groundwater Basin, and is bounded to the east by a topographic divide, beyond which is the Broadwell Valley Groundwater Basin. There are no groundwater basins bordering the Lavic Valley basin to the north and south of the project area, due the presence of the Fort Cady Mountains (north) and Rodman Mountains and Lava Bed Mountains (south). Groundwater flow in the Lavic Valley basin is poorly defined, and outflow is interpreted to occur to the east of Broadwell Valley, with no localized groundwater discharge such as evapotranspiration or discharge to springs or a river.

The nearest industrial well, owned by Candeo Lava Products, is located 3.5 miles east of the project ore body. No other water wells are known to exist within the vicinity of the project to the north, south, or east. Water level measurements from the Candeo Lava Products well were not available for this study. The next closest water well to the north, south, or east is in the town of Ludlow, 14 miles east of the project. The location of groundwater wells that provide representative static groundwater elevations for the region surrounding the project are provided in Figure 7.4.

Figure 7.4 Project Area Groundwater Basins and Surrounding Area Wells, Fort Cady Project, San Bernardino, CA

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The nearest non-industrial groundwater well outside of the immediate project area is a non-potable water well located 5.6 miles northwest of the project ore body and 0.4 miles southeast of the I-40 rest area (Well 1807, Figure 2). Private drinking water wells associated with rural residences are located greater than 6.5 miles west of the Project, at the eastern edge of the town of Newberry Springs. Irrigation wells are located further west, in Newberry Springs, the closest of which is approximately 10 miles west of the project. The Pisgah Fault separates these residential and irrigation wells from the project area, such that they are not within the same regional groundwater flow system and are not hydraulically connected.

Although rarely present in the vicinity of the Project, surface water flows in a northwesterly direction past the project area from the Rodman Mountains to the south and the Pisgah Crater topographic divide to the east. There are no springs or streams of significance in the vicinity of the project. Surface water-related features consist of unnamed dry washes that may carry water during heavy storm events. These washes generally drain west through the project area toward the Troy Lake playa in Newberry Springs.

7.3.2

Project Area Wells

The static depths to groundwater in the project area are 230–390 feet below ground surface (bgs). The depths to groundwater in the project area are generally shallower at lower elevation wells and deeper at higher elevation wells. In the fault bounded wedge between the Pisgah Fault and Fault B, static groundwater is 230–260 feet bbelow ground surface (bgs). Groundwater to the west of the Pisgah Fault is present in quaternary alluvial fan sediments of the Lower Mojave River Valley Groundwater Basin at depths of 200–265 feet bgs in project wells MWW-1, MWW-S1, and MWW-2. There is approximately a 30 to 40 ft water level differential on the east and west sides of the Pisgah Fault, which is regionally recognized as a barrier to groundwater flow, and forms a groundwater basin boundary. Groundwater in the vicinity of Fault B at project wells TW- 1, PW-1, and PW-2, is found at depths of 350–390 feet bgs in coarser alluvial sediments to the east of Fault B (PW-1 and PW-2) and a mix of alluvial and fine playa sediments to the west of Fault B (TW-1).

No U.S. drinking water aquifer has been encountered in the project area. Monitor wells drilled in 2021 by FCCC as part of its permitting compliance has not encountered groundwater above the Unit 3 sediments other than small quantities of perched water found underneath near-surface lava flows. Limited water has been found in the ore body but does not meet the definition of a U.S. drinking water aquifer.

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7.3.3

Hydraulic Properties

Testing for hydraulic properties of the colemanite and evaporates/claystones containing the colemanite have occurred on several occasions. Beginning in 1980 Duval had Core Laboratories, Inc. conduct injectivity tests on one-inch cores from SMT-1. The samples were extracted with toluene, leached of salts with cool methanol, and dried in a controlled humidity oven. Permeability to air and Boyle’s Law porosity were determined for each sample. The injectivity tests were performed at the reservoir temperature of ““Simulated formation water was flowed through the core until equilibrium occurred and a minimum of 3 pore volumes had been injected. Permeability to water was determined at equipment.” Sulfuric acid and hydrochloric acid solutions were injected through the core samples after which permeability to acid solutions was determined. While detailed information on the testing procedures conducted by Core Labs is available, detailed QA/QC procedures are not available. Initial permeability was found to range from 1.35 x 10-9 to 2.9 x 10-10 cm/sec in 1990, In-Situ Inc. conducted a multiple well constant rate injection test to determine direction tendencies of hydraulic properties of the mineral deposit. In-Situ also investigated effects of previous injection/recovery testing. Using a Badger flow meter, a HEREMIT data logger, and pressure transmitters, water-level responses were measured in the injection well and six nearby observation wells. In-Situ used the Cooper and Jacob method to analyze data from each well and applied the Papdopulos Method to determine directional permeability. In-Situ’s work confirmed earlier work that permeability and transmissivity of the deposit are low. Hydro- Engineering (1996) summarized some of the testing and provided interpretations of prior testing conducted in 1981 and 1990. The mineralized sequence of rocks transmissivity (T) is estimated at 10 gal/day/ft, or 1.3 ft2/day. Assuming the colemanite mineralized sequence occurs over an approximate 300 ft thickness, then the native hydraulic conductivity (K) over this thickness is estimated at 4.5 x 10-3 ft/day. This K value is of a similar magnitude as estimated by Simon Hydro-Search (1993) of 8.2 x 10-3 to 2.2 x 10- 2 ft/day (K converted from millidarcy units).The storage coefficient (S) of the ore body was estimated by Hydro-Engineering (1996) at 2.5 x 10-6. Increases in transmissivity, hydraulic conductivity and storage coefficient will occur as colemanite is dissolved from the formation. Hydro-Engineering (1996) estimated the end-point permeability of the ore body formation after colemanite dissolution would be approximately 30 times higher, and a long- term storage coefficient may be approximately 1.1 x 10-5. The end-point hydraulic properties are still low, owing to the fact that a majority of the formation is evaporites (anhydrite) and claystone that will not be dissolved. The end-point porosity of the ore body formation after mining is predicted to be 15 percent (Simon Hydro-Search, 1993; Core Laboratories, 1981) based on the colemanite content within the sediments and laboratory core analyses.

Injection and pumping tests were conducted in 1981 by Duval Corporation, 1986-1987 by Mountain States Minerals, and between 1996-2001 by Fort Cady Minerals Corporation. Injection was conducted at 150-300 psi pressures in the 1982 testing, with injection flow rates mostly of 1.5-2.5 gpm, indicative of the hydraulically tight nature of the claystone hosting the deposit. In the 1986-1987 testing, rates of 1.3 to 5.3 gpm were observed over testing periods lasting from 6 to 71 days. The mudstone and claystone sediments above and below the ore body evaporites are also understood to be of very low transmissivity. Pump test results provided by Confluence Water Resources (Confluence, (2019) provided an estimate of the hydraulic conductivity in the 10-5 range.

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In 2018, Confluence Water Resources, LLC (CWR) was retained by FCCC to characterize hydrology east of Fault B and approximately 3,500 ft. east of the colemanite deposit. CWR found a significant groundwater resource east of Fault B and the fault is a barrier to groundwater flow. Stable isotope analytical results were compared against Nevada Meteoric Water Lines and found that the aquifer east of Fault B and the aquifer west of the Pisgah Fault have different origins and the limited groundwater found between the two faults is of a different origin than both aquifers. Recovery rates from wells between the two faults, which includes the colemanite deposit, are less than one gal/min as would be expected in mudstones and claystones with very limited groundwater present.

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8	SAMPLE PREPARATION, ANALYSES AND SECURITY

Between September 2017 and October 2017, APBL completed 14 holes for 23,111 ft. as part of a confirmatory resource drilling program. Assay results from all 14 drill holes were used in the mineral resource estimate. There are 2,113 samples from the 2017 drilling program representing 1,713 ft. of core. In conjunction with the 2017 drilling program, 29 historical drill holes completed by Duval and four holes completed by FCMC have been utilized in the mineral resource estimate. There are 3,672 samples from the historic drilling representing a cumulative total 10,831.3 ft. of core. The QA/QC procedures for the historic drilling are unknown though the work products compiled during the historic drilling suggests it was carried out by competent geologists following procedures considered standard practice at that time.

Discussions held with Pamela A.K. Wilkinson, who was an exploration geologist for Duval at the time of drilling and sampling, indicate that Duval had internal quality control and quality assurance procedures in place to ensure that assay results were accurate by Duval utilized their Tucson, West Texas (Culberson Mine) or New Mexico (Duval Potash mine) laboratories for analytical work carried out at Fort Cady. Geochemical analyses were carried out using X-Ray Fluorescence Spectrometry (XRF). XRF results were reportedly checked against logging and assay data.

8.1

SAMPLING METHOD AND APPROACH

Entire core sequences were sampled. Sample intervals were determined at the time of logging are based on changes in lithology, mineralogy, and bedding. Sample intervals range from 0.2 to 6.6 ft. with an overall average sample length of 2.66 ft. Following determination of sampling intervals, core was split in half using a core splitter. One half of the core is used for the analytical sample with the remaining half core being returned to the core box for archiving. Samples are then placed into labeled plastic sample bags along with a pre-numbered sample tag. A companion sample tag is placed back in the core box marking the interval sampled. Samples were dispatched by commercial carrier to the Saskatchewan Research Council (SRC) for geochemical analysis. SRC has been accredited by the Standards Council of Canada and conforms with the requirements of ISO/IEC 17025.2005

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8.2

SAMPLE PREPARATION, ANALYSES AND SECURITY

Upon receipt of samples from APBL, SRC would complete an inventory of samples received, completing chain of custody documentation, and providing a ledger system to APBL tracking samples received and steps in process for sample preparation and analysis. Core samples are dried in their original sample bags, then jaw crushed. A subsample is split out using a sample riffler. The subsample is then pulverized with a jaw and ring grinding mill. The grinding mill is cleaned between each sample using steel wool and compressed air or by silica sand. The resulting pulp sample is then transferred to a barcode labeled plastic vial for analysis.

All samples underwent a multi-element Inductively Coupled Plasma Optical Emission Spectroscopy (ICP-OES), using a multi-acid digestion for Ag, Al₂O₃, Ba, Be, CaO, Cd, Ce, Cr, Cu, Dy, Er, Eu, Fe₂O₃, Ga, Gd, Hf, Ho, K2O, La, Li, MgO, MnO, Mo, Na₂O, Nb, Nd, Ni, P₂O₅, Pb, Pr, Sc, Sm, Sn, Sr, Ta, Tb, Th, TiO₂, U, V, W, Y, Yb, Zn, and Zr. Boron was also analyzed by ICP-OES but undergoes a separate digestion where an aliquot of the sample is fused in a mixture of NaO₂/NaCO₃ in a muffle oven, then dissolved in deionized water, prior to analysis. Major oxides (Al₂O₃, CaO, Fe₂O₃, K₂O, MgO, MnO, Na₂O, P₂O₅ and TiO₂) are reported in weight percent. Minor, trace, and rare earth elements are reported in ppm. The detection limit for B is 2 ppm and 1 ppm for Li.

For the 2017 drilling program, a total of 2,118 core samples and 415 control samples were submitted for multi-element analysis to SRC. APBL submitted control samples, in the form of certified standards, blanks and coarse duplicates (bags with sample identification supplied by APBL for SRC to make duplicate samples). In addition to these control samples, SRC also submitted their own internal control samples in the form of standards and pulp duplicates. A summary of all the QAQC control samples submitted to SRC is shown in Table 8.1.

Table 8.1 Summary of QA/QC Control Samples


Submitted By	Drilling Type		Number of Holes		Meters Drilled		Standards			Blanks			Coarse Duplicates			Pulp Duplicates			Total Frequency			Primary Samples			Total
APBL		Rotary		14		4,692.10		0			0			0			0						0			0
		Diamond Tail		14		2,353.70		144			135			136			0						2,118			2,533
		Total		14		7,045.80		144			135			136			0						2,118			2,533
						Frequency		6.80	%		6.40	%		6.40	%					19.60	%		83.60	%		100	%
SRC		SRC Internal QAQC						151									82
SRC						Frequency		7.10	%								3.90	%		11.00	%

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Certified standards SRM 1835 and SRM 97b, prepared by the National Institute of Standards and Technology, were submitted as part of the APBL QA/QC procedures, the results of which are shown graphically on Figures 8.1 and 8.2. Standard deviations shown are for the SRC assays. No two standards in any single batch submission were more than two standard deviations from the analyzed mean, implying an acceptable level of precision of SRC instrumentation.

Figure 8.1 Assay Results of Standard SRM1835

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Figure 8.2 Assay Results of Standard SRM97b

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SRC assayed two different standards, CAR110/BSM and CAR110/BSH, for its own QC protocol. CAR110/BSM is designated as a “medium boron standard”. CAR110/BSH is designated as a “high boron standard”. Figures 8.3 and 8.4 display the analytical results for the certified standards. The analytical precision for analysis of both CAR110/BSM and CAR110/BSH is also reasonable, with no two standards in any single batch submission being more than two standard deviations from the analyzed mean.

Figure 8.3 Assay Results for SRC Standard CAR110/BSM

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Figure 8.4 Assay Results for SRC Standard CAR110/BSH

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Blank samples inserted by APBL consisted of non-mineralized marble. One hundred and thirty-five blank samples were submitted, all of which had assay results of less than 73 ppm B. The level of boron detected in the blanks is likely sourced from pharmaceutical (borosilicate) glass used during sample digestion. These boron concentrations are considered immaterial in relation to the boron levels detected in the colemanite mineralization and do not appear to represent carryover contamination from sample preparation. Lithium levels in the blank samples are also at acceptable levels with the majority of assays <15 ppm Li. The four highest Li levels in the blanks immediately followed samples that contained relatively high Li concentrations. Overall, the concentration of the primary elements of interest (B and Li) in the blanks are at levels considered to be acceptable, implying a reasonable performance for sample preparation. The results of the blanks for B and Li are plotted in Figures 8.5 and 8.6.

Figure 8.5 Sample Blank Assay Results for Boron

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Figure 8.6 Sample Blank Assay Results for Lithium

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A total of 136 duplicate samples were submitted to the SRC. APBL commissioned SRC to compose coarse duplicate samples using a Boyd rotary splitter. Figures 8.7 and 8.8 show the assay results of duplicate samples for B and Li. As can be seen from the regressions, there is a good correlation between original and duplicate samples.

Figure 8.7 Duplicate Sample Results for Boron

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Figure 8.8 Duplicate Sample Results for Lithium

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Figure 8.9 displays a HARD (half absolute relative difference) plot for the duplicates. This highlights reasonable precision for the duplicates. Regression and HARD results were also plotted for pulp duplicates assayed in SRC’s own QC protocol shown in Figures 8.10 and 8.11. These also show a reasonable level of precision.

Figure 8.9 HARD Diagram for APBL Duplicate Samples.

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Figure 8.10 SRC Duplicate Results

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Figure 8.11 SRC Duplicates HARD Diagram

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The QP believes reasonable care has been taken to collect and dispatch sample samples for analysis. The QA/QC program has shown the analyses are viable with a minimum of dispersion or contamination errors. The QP considers the sampling program to be of sufficient quality to support a mineral resource estimate.

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9	DATA VERIFICATION

During the site visit, the QP examined the core for five of the 2017 drill holes completed by FCCC. Core has been safely stored in a designated storage building nearby the mine site office and is in good condition. The QP examined the core and compared the core to the geologic logs and sample interval records and found good agreement with the log descriptions and with no discrepancies with sample intervals.

Historic drilling location records were originally recorded in California State Plane coordinates or in metes and bounds. The QP checked historic drilling location data to ensure these records had been properly converted to UTM coordinates, the coordinate system used in the 2017 drilling program. All historic location data has been properly converted to the current UTM coordinate system.

The QP was provided drilling records, sample intervals, and assay results in Excel Workbook files that were used as input for the drill hole database. Through a variety of data checks drill hole information was evaluated for duplicate entries, incorrect intervals, lengths, or distance values less than or equal to zero, out-of-sequence intervals and intervals or distances greater than the reported drill hole length. Historical drill hole records were also checked against relevant Duval and FCMC data sets. A review comparing original field logs and assay reports showed the data to have been transcribed accurately into the Excel files.

The QP believes adequate care has been taken in preserving and transcribing the historic data to digital format and 2017 drill hole data accurately corresponds back to the sample ledger and assay certificates. The QP believes that the data as used are adequate and suitable for a mineral resource estimate.

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10	MINERAL PROCESSING AND METALLURGICAL TESTING

10.1

MINERAL CHARACTERISTICS

Colemanite (2CaO • 3B₂O₃ • 5H₂O) is a hydrated, calcium borate mineral with 50% B₂O₃ and is found in evaporite deposits of alkaline lacustrine environments. The mineral is semi-hard with a Mohs hardness of 4.5 and forms as discreet monoclinic, prismatic crystals or masses. Colemanite typically forms as translucent colorless, white or gray crystals with a vitreous luster. Colemanite is insoluble in water but soluble to hydrochloric acid (HCl) and sulfuric acid (H₂SO₄).

In-situ solution mining is the proposed extraction technique for the Fort Cady deposit. In-situ solution mining depends on the following hydrologic characteristics: void spaces and porosity, permeability, ore zone thickness, transmissivity, storage coefficient, water table or piezometric surface, and hydraulic gradient (Bartlett, Solution Mining, 1998) as well as reaction and extraction method efficiencies.

10.2

SOLUTION MINING

APBL intends to use solution mining by injecting an acid solution via a series of wells (well field) into the mineralized horizons. The acid solution reacts with the colemanite forming a pregnant leach solution (PLS) containing boric acid (H₃BO₃). There are various ways of developing the well field for in-situ leaching, including “push-pull” where wells function as both as injection and recovery well; line drive; and multiple spot patterns. In addition to the vertical wells, horizontal drilling for well development is also being evaluated as a potential option for the Project. The mine wellfield development and the pattern will ultimately depend on the hydrogeologic model and the cost benefit analysis of various patterns and options.

The leaching of the colemanite will occur via the injection of a solution with a dilute concentration of HCl into the deposit through the wells. The injection fluid will remain in the formation and extracted after sufficient contact time with the colemanite. The concentration of HCl in the injection solution is one of the key control variables for the mining process. Higher concentrations of HCl promote reaction with the colemanite, while excessive HCl will increases the reaction with minor impurities such as aluminum, magnesium, iron, anhydrides, and calcite.

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10.3

PROCESSING

Mineral processing and metallurgical testing are ongoing for the Project. FCCC has considered the following methods of extraction of boric acid from pregnant leach solution (PLS):

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Evaporative concentration of PLS followed by a crystallization process with by final product washing and drying.

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Regeneration of Hydrochloric acid via reactions of calcium chloride in the PLS with sulfuric acid, creating calcium sulfate (gypsum).

•

Regeneration of hydrochloric acid via the Mannheim process. (This is an alternative process design).

•

Concentration of boric acid in PLS via solvent extraction (SX) prior to crystallization. (This is an alternative process design)

In 2019, Swenson Technology, Inc was engaged to perform crystallization tests; and Hazen Research Inc was engaged to perform solvent extraction tests. These tests were under the direction of Mike Rockandel Consulting LLC, which produced a process design based on these methods, utilizing Metsim^® software. FCCC then engaged Aquatech to produce equipment-specific modelling and to supply crystallization and evaporation equipment for a test plant. PLS leachate samples used for this testing were from a small quantity of concentrated material obtained from the deposit.

In 2021, FCCC engaged Agapito Associates and Hazen Research (Hazen) to produce solid core leaching tests, from representative core samples obtained from the 2017 drilling program. Hazen’s analytical facilities are certified by the National Institute of Standards and Technology and by the U.S. Environmental Protection Agency. Cores were selected by Terra Modelling Services (TMS) from across the ore body to represent average content of boric acid and calcite, and 20 core samples were leach tested to estimate mine PLS content. Based on the chemical composition data obtained from these tests, additional equipment testing was planned along with process plant modelling. Also in 2021, FCCC engaged Hargrove and Associates (Hargrove) to lead a modified process design. Hargrove is currently producing a process design for a commercial plant. Engineering and construction were also initiated in 2021 for the SSBF. Once operational, the SSBF should provide many of the necessary parameters that will lead into the design of the processing plant for initial production of 90 kstpa boric acid and 80 kstpa SOP.

For production of sulfate of potash (SOP), Desmet Ballestra Group was engaged to provide a process design to make SOP from potash (MOP) with their proprietary Mannheim furnace design. Ballestra provided process design for a SOP plant. Detailed construction design for a Mannheim furnace plant has not been completed nor has a decision to produce SOP at this time.

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Mike Rockandel Consulting LLC also developed an alternative processing design using solvent extraction. Solvent extraction has been modeled to achieve a recovery rate of 92%. Hargrove is currently working on an alternative plant design, utilizing Aspen OLI chemical process simulation. A recovery rate has not been established by Hargrove.

The above-mentioned companies have been selected as consultants and contractors, based on their reputation and capabilities, and been established in the mining and mineral processing industry for a significant time. (Certification information of their laboratories are not available at this time.)

Potentially negative factors that may impact processing and economic extraction include:

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High concentrations of Iron and other metals in the PLS

•

High levels of corrosion

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Failing to to provide continuous, steady and acceptable head grades of boric acid in the PLS.

The QP is of the opinion that FCCC has taken adequate steps in advancing testing and process engineering for the Fort Cady Project. Once operational, the SSBF should provide most of the remaining inputs to proceed with final plant design and economic analysis for the Project.

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11	MINERAL RESOURCE ESTIMATES

11.1

INTRODUCTION

In December of 2018, Mr. Louis Fourie of Terra Modelling Services (TMS) completed an updated JORC resource report for APBL’s Fort Cady Project. That report identified a Measured plus Indicated mineral resource estimate of 52.7 million tonnes (Mt) containing an average grade of 6.02% B₂O₃ and 367 ppm of Li. There have been no additional exploration activities on the Project since that time though there have been some changes in the mineral holdings. The QP has conducted an audit of the geologic model completed by TMS and has used that model to update the mineral resource estimate.

11.2

RESOURCE DATABASE

The database used for resource estimate includes 34 holes completed by Duval, 3 holes completed by FCMC, and 14 holes completed by APBL for a cumulative total of 51 drill holes and a cumulative sampled length of 24,823.6 m. (81,421.4 ft.). Table 11.1 summarizes the drilling database. The database was provided to Millcreek in a digital format and represents the Project’s exploration dataset as of (July 19, 2021). Drilling coordinates in the database are in UTM NAD 83-11, and depths and elevations are reported in meters. Borate is listed as weight percent (%) B₂O₃ and Li as ppm. The drilling database contains 5,775 analytical values for B₂O₃ and 5,193 analytical values for Li.

Core recovery for the 2017 drilling program ranged from 93% to 100% with an overall average of 97.60%. Core recovery records for earlier drilling conducted by Duval and FCMC are not available, but based on missing intervals in the drilling database, core recovery likely exceeded 90% in the core drilling.

The QP has completed a thorough review and verification of the drilling database and found the database to be sufficient for resource modeling.

11.3

GEOLOGIC MODEL

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Table 11.1 Summary of Drilling Database


HoleID	Cumulative Core Length (m)		Cumulative Sample Length (m)		B₂O₃ Analyses		Li Analyses
17FTCBL001		111.13		88.90		82		82
17FTCBL002		91.74		87.74		107		107
17FTCBL003		93.11		92.80		91		91
17FTCBL004		143.77		142.71		162		162
17FTCBL005		107.35		104.76		150		150
17FTCBL006		95.34		90.47		83		83
17FTCBL007		176.27		166.09		207		207
17FTCBL008		128.96		127.20		153		153
17FTCBL009		119.33		118.51		120		120
17FTCBL010		133.81		126.50		176		176
17FTCBL011		135.72		134.79		155		155
17FTCBL012		142.77		138.42		212		212
17FTCBL013		138.99		136.75		155		155
17FTCBL014		157.43		156.99		260		260
DHB-01		162.49		158.41		184		184
DHB-03		212.90		212.12		213		213
DHB-05		207.26		207.26		179		179
DHB-06		175.57		155.42		124		124
DHB-07		204.83		204.06		179		179
DHB-08		224.63		224.63		186		186
DHB-09		170.69		170.69		138		138
DHB-10		139.08		81.79		86		86
DHB-11		112.90		73.28		86		86
DHB-12		120.67		74.04		85		0
DHB-13		102.57		61.17		70		70
DHB-14		117.63		75.71		80		0
DHB-15		125.70		56.18		51		51
DHB-16		145.48		122.62		138		138
DHB-17		141.25		104.49		151		151
DHB-18		139.48		92.32		105		105
DHB-19		106.68		59.40		74		74
DHB-21		26.33		25.93		39		39
DHB-22		135.94		101.81		135		135
DHB-23		136.24		100.80		114		114
DHB-24		146.00		120.00		119		119
DHB-25		173.74		134.87		152		152
DHB-26		121.37		81.99		106		106
DHB-27		132.71		67.07		95		95
DHB-28		128.62		80.07		115		115
DHB-29		120.64		75.28		101		101
DHB-30		137.53		68.49		83		83
DHB-31		49.00		57.36		41		0
DHB-33		111.19		92.17		80		0
DHB-34		68.76		87.47		79		0
P1		60.96		60.96		20		0
P2		54.87		64.01		21		0
P3		54.87		54.87		18		0
P4		83.82		54.87		34		0
SMT-1		23.77		23.25		57		57
SMT-2		103.57		24.14		55		0
SMT-3		512.00		24.35		69		0

Total		6767.46		5245.98		5775		5193

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patterns of mineralization into four mineralized horizons, two non- mineralized or weakly mineralized interbeds and two non-mineralized horizons bounding the deposit. These horizons are listed in Table 11.2

Table 11.2 Modelled Horizons


Horizon	Abbreviation	Thicknes Range (m)	Average Thickness (m)	Composite B2O3 Range (wt.%)	Composite Li Range (ppm)
Overburden	OBN	317.0 - 507.7	381.8	NA	NA
Upper Mineralised Horizon	UMH	0.1 - 12.5	4.3	0.87 - 14.45	99 - 588
Upper Interbed	UI	0.1 - 16.7	6.7	0.5 - 4.1	108 - 623
Major Mineralised Horizon	MMH	0.7 - 69.4	27.4	2.6 - 17.6	98 - 550
Medial Interbed*	MIB	6.5 - 5.2	9.7	0.3 - 1.9	386 - 492
Intermediate Mineralised Horizon	IMH	1.8 - 58.3	22.5	0.7 - 12.0	23 - 534
Lower Mineralised Horizon	LMH	0.0 - 53.9	19.7	0.2 - 5.7	91 - 534
Lower Sandstone*	LSS	0.1 - 58.6	15.6	NA	NA

*	Horizon not fully penetrated. NA: Not Applicable

The grid model was constructed across the deposit area, with a grid cell size of 25 m. x 25 m. Grids represent the bounding elevation surfaces of key horizons, thicknesses, and analytical grades. Mineral horizon grids were interpolated using an Inverse Distance Squared (ID2) algorithm. Mineralization is spatially defined by a resource boundary using a distance of 150 m. from the last intersection of mineralization in a drill hole. Grids are masked to the outside of the resource boundary.

11.4

GRADE ESTIMATION & RESOURCE CLASSIFICATION

Using composites for each mineralized horizon, variography was successful for B₂O₃ grades for the Major Mineralized Horizon (MMH), Intermediate Mineralized Horizon (IMH), and the Lower Mineralized Horizon (LMH) and are summarized in Table 11.3. Variogram modelling was unsuccessful for the Upper Mineralized Horizon and with Li in all horizons. Grids representing B₂O₃ grades for the MMH, IMH, and LMH were constructed using Ordinary Kriging using the constructed variograms. ID2 interpolation was used with all remaining grade grids using the same spatial limits established with the horizon grids.

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Table 11.3 Modelled Variograms


Horizon	Type	Nugget	First Structure	Second Structure
MMH	Spherical, omnidirectional	0	200	400
IMH	Spherical, omnidirectional	0.2	180	450
LMH	Spherical, omnidirectional	0.2	530	—

Based on the variography above, the deposit was classified as follows:

•

Measured Resource Category: based on a maximum spacing between mineralized drill holes for each horizon of 200m.

•

Indicated Resources Category: based on a maximum spacing between mineralized drill holes for each horizon of 400m.

•

Inferred Resources Category: based on a maximum spacing between mineralized drill holes for each horizon of 800m.

Drilling and sampling density is sufficient that no further limits on classification are required.

11.5

MODEL VALIDATION

Drilling data was loaded into Carlson Mining to compare drill hole postings with the provided grids representing the top and bottom surfaces for each mineralized horizon. This comparison was done using a grid inspector tool in Carlson Mining that enables simultaneous viewing of drill hole data along with grid values at each drilling location. The QP found the resulting comparisons to be satisfactory. This step was repeated comparing drill hole composite grades from drill hole data with grids representing the grades of B₂O₃ and Li for each mineralized horizon. While there are some fluctuations with grid values generated by kriging and ID2, these fluctuations are small and within expected ranges.

The gridded model was evaluated using a series of swath plots. A swath plot is a graphical display of the grade distribution derived from a series of bands, or swaths, generated as sections through the deposit. Grade variations from the ordinary kriging model are compared to nearest neighbor (NN) searches on drill hole composites.

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On a local scale, the NN search does not provide reliable estimations of grade but, on a much larger scale, it represents an unbiased estimation of the grade distribution based on the underlying data. If the model estimation completed by ordinary kriging is unbiased, the grade trends may show local fluctuations on a swath plot, but the overall trend should be similar to the NN distribution of grade. Three swath plots are shown in Figure 11.1

Finally, the QP completed a separate estimate in Carlson Mining following the parameters used by TMS to the defined resource boundary. This separate resource estimate was within 3.6% of the TMS estimate. The QP considers the difference negligible considering the comparison uses two different modelling software packages.

Figure 11.1 Grade Variation Swath Plots

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11.6

DENSITY MEASUREMENTS

The 2017 drilling program included the collection of 777 density measurements from core samples. Density determinations were made using the weight in air/weight in water method. The weighted average bulk density determined from the 381 samples collected through the mineralized horizons is 2.18 g/cm³. and has been used as the bulk density in resource estimation.

11.7

CUT-OFF GRADE

Cut-off grades ranging from 2.0% to 8.0% B₂O₃ are shown in Table 11.4. A 5.0% B₂O₃ cut-off grade was previously established by Duval and was carried forth by TMS in their JORC resource reporting for APBL. This cut-off grade has been used for resource estimation purposes while work continues to determine pregnant leach solution (PLS) brine grade and processing plant costs. A 5% B₂O₃ cut-off grade equates to an 8.9% H₃BO₃ grade which is considered adequate and appropriate to account for mining losses and recovery with solution mining while additional testing is carried on dissolution rates and recovery by Agapito Associates and with the engineering and design of the SSBF.

Table 11.4 Fort Cady Project Cut-off Grades

FCCC Controlled (Owned & Leased)

Uncontrolled (California State Land & Elementis Not Leased)

Cut-Off

Grade %

Tonnes

B2O3 %

Li %

Cut-Off

Grade %

Tonnes

B2O3 %

Li %

5,140,699

9.16

326

1,004,849

8.22

406

26,427,333

7.72

349

6,736,430

7.57

382

81,587,306

6.85

325

17,018,864

6.96

365

108,977,349

6.52

323

23,183,941

6.82

366

145,656,514

6.03

330

29,517,682

6.11

347

202,405,283

5.31

330

40,256,782

5.42

342

273,029,338

4.60

320

53,516,614

4.70

341

The QP believes the current cut-off grade is conservate. Preliminary plant processing has been using an average B₂O₃ grade of 5%. At a 5% cut-off grade, average grade for the deposit is 6.53% B₂O₃. However, without dissolution testing at known grades of B₂O₃, it is not possible to determine effective recovery. Effective recovery along with detailed economic analysis will be needed for reserve estimation.

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11.8

MINERAL RESOURCE ESTIMATION

Results of the mineral resource estimation are shown in Table 11.5. The resource estimate contains a combined 97.55 Mt of Measured plus Indicated resources with an average grade of 6.53% B₂O₃ and 324 ppm Li, using a 5% cut-off grade for B₂O₃. The mineral resource estimate also identifies 11.43 Mt of Inferred resources under mineral control by FCCC. Approximately 91.21 Mt or 94% of the mineral resources controlled by FCCC occurs within the approved Operating Permit region approved for commercial-scale operations which was awarded to FCCC in 1995. 27.58 Mt or 25% of the total mineral resources is contained within the electrical transmission corridor operated by SCE. While SCE maintains control of the surface and resources to a depth of 500 ft., it does not impinge on FCCC’s mineral rights for B₂O₃ and Li which occur at depths in excess of 1,000 ft. The resource boundary contains 23.18 Mt of Uncontrolled Resources, resources APBL does not have mineral rights to exploit. Uncontrolled resources are shown in Table 11.5. Figures 11.2 through 11.5.

Regulation S-K 1300 requires a current economic assessment to be completed which provides a reasonable basis for establishing the prospects of economic extraction of the mineral resource estimation. Key assumptions used in the economic assessment include; ISL mining operation delivering 5% boric acid in solution to an above ground processing plant; operating costs of $587 per tonne of boric acid produced; 92% conversion of boric acid in solution to saleable boric acid powder (recovery rate); 80% recovery of in-situ boron (extraction ratio) and an average sales price of US$900 per tonne of boric acid. A high level financial model using a discount rate of 8% delivered a positive net present value to support the cut-off grade and more broadly the resulting mineral resource estimation. Potential by-product production of lithium, SOP and gypsum has been excluded from the financial model and may ultimately provide the potential for a reduction in the cut-off grade.

The QP is not aware of any known environmental, permitting, legal, title, taxation. socio-economic, marketing, or other relevant factors that could affect the mineral resource estimate.

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Table 11.5 Fort Cady Project Mineral Resource Estimate*, October 15, 2021


Measured Resource	Horizon	Tonnage (Mt)		B₂O₃ (wt. %)		H₃BO₃ (wt. %)		Lithium (ppm)		B₂O₃ (Mt)		H₃BO₃ (Mt)
FCCC Fee Lands	UMH		0.03		5.73		10.17		259		0.00		0.00
	MMH		7.01		6.31		11.20		317		0.44		0.79
FCCC Fee Lands - Transmission Corridor	MMH		5.24		6.51		11.55		293		0.34		0.61
FCCC-Elementis Leased Lands	UMH		0.75		6.64		11.79		264		0.05		0.09
	MMH		18.59		6.74		11.98		349		1.25		2.23
	IMH		4.34		6.35		11.27		324		0.28		0.49

Total Measured Resource			35.96		6.57		11.67		330		2.36		4.20


Indicated Resource	Horizon	Tonnage (Mt)		B₂O₃ (wt. %)		H₃BO₃ (wt. %)		Lithium (ppm)		B₂O₃ (Mt)		H₃BO₃ (Mt)
FCCC Fee Lands	UMH		0.87		5.73		10.17		259		0.05		0.09
	MMH		29.00		6.47		11.50		329		1.88		3.33
FCCC Fee Lands - Transmission Corridor	MMH		20.41		6.51		11.55		293		1.33		2.36
FCCC-Elementis Leased Lands	UMH		0.31		6.68		11.87		251		0.02		0.04
	MMH		7.70		6.74		11.98		349		0.52		0.92
	IMH		3.29		6.40		11.37		324		0.21		0.37

Total Indicated Resource			61.59		6.51		11.55		318		4.01		7.12

Total Measured + Indicated Resource			97.55		6.53		11.61		324		6.37		11.31


Inferred Resource	Horizon	Tonnage (Mt)		B2O3 (wt. %)		H₃BO₃ (wt_. %)		Lithium (ppm)		B₂O₃ (Mt)		H₃BO₃ (Mt)
FCCC Fee Lands	UMH		0.03		5.73		10.17		259		0.00		0.00
	MMH		6.46		6.55		11.42		334		0.42		0.75
	IMH		0.59		5.64		10.01		330		0.03		0.06
FCCC Fee Lands - Transmission Corridor	MMH		1.93		6.51		11.55		293		0.13		0.22
FCCC-Elementis Leased Lands	MMH		0.27		6.74		11.98		349		0.02		0.03
	IMH		2.14		6.32		10.48		330		0.14		0.24

Total Inferred Resource			11.43		6.40		11.37		324		0.74		1.31

*	Using a 5% B₂O₃ cut-off grade.

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Table 11.6 Uncontrolled Resources


Resource	Classification	Horizon	Tonnage (Mt)		B₂O₃ (wt. %)		H₃BO₃ (wt_. %)		Lithium (ppm)		B₂O₃ (Mt)		H₃BO₃ (Mt)
	Measured	MMH		0.93		6.98		12.40		366		0.07		0.12
California State Land	Indicated	MMH		14.61		6.98		12.40		366		1.02		1.81
	Inferred	IMH		0.81		5.44		9.66		333		0.04		0.08
	Measured	UMH		0.13		7.15		12.69		228		0.01		0.02
		MMH		2.28		5.81		10.32		341		0.13		0.23
Elementis Not Leased	Indicated	UMH		0.23		6.72		11.93		230		0.02		0.03
		MMH		3.68		7.10		12.62		401		0.26		0.46
	Inferred	UMH		0.03		6.09		10.82		239		0.00		0.00
		MMH		0.50		6.23		11.06		371		0.03		0.05

Total Uncontrolled Resources				23.18		6.82		12.1		366		1.58		2.81

*	Using a 5% B₂O₃ cut-off grade.

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12	MINERAL RESERVE ESTIMATES

There are no mineral reserve estimates to report at this time.

Agapito is currently conducting additional dissolution testing that may yield different dissolution recoveries for colemanite. Likewise, engineering and construction is currently in progress for the SSBF from which plant recovery and other economic factors will be determined. Dissolution testing and operation of the SSBF will provide the necessary parameters for determining the mineral reserve estimate.

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13	MINING METHODS

The Project will be employing ISL as its mining method to recover boric acid and Li from the mineralized horizons. Depth and grade of the deposit precludes conventional mining techniques as effective methods for economical extraction of ore. With ISL mining, there is no stripping of waste rock or underground development required for this project. Mine development steps include constructing injection/recovery wells, installing extraction equipment (pumping or air-lifting) on wells, and piping to transport leach solutions and PLS. Mining fleet and machinery are not required for this project.

In 2021, Agapito Associates was engaged to complete a mine design for the Project assuming a production rate of 100,000 tons/year boric acid. This production rate should correspond to 1,011 gallons/min of PLS to the processing plant, based on preliminary design data for the processing plant using a plant recovery of 95%.

Preliminary work completed by Agapito calls for the installation of 100-ft spaced injection/recovery wells (push-pull). These wells are to operate each as injection and recovery wells where leach solution in pumped into the well and after a prescribed residence time is retrieved from the same well for processing. This method will be used until dissolution of the colemanite in the deposit progresses to where conduit flow is established between wells. Once conduit flow is established, certain wells will be become injection wells with other wells becoming recovery wells allowing continuous mining. Preliminary mine planning estimates a recovery of 80.6% of the total resource tons before mining and plant losses.

For the mine design, the mineral resource area has been subdivided into three blocks for development. Block 1 comprises the northern third of the resource area, Block 2 occupies the central portion of the resource area, and Block 3 comprises the southern third of the mineral resource area. The mine design calls for developing Block 2, the central region, first. Figure 13.1 projects well development for Block 2 through the end of 2100 assuming 100,000 tons of boric acid per year of production.

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Figure 13.1 Block 2 Mining Sequence

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Certain areas of the mineral resource are assumed to be inaccessible for well development due to poor accessibility from surface features and have been excluded from mine design excluded. This equates to 11.8% of the mineral resource being excluded. Of the remaining resource 91.3% of the remaining resource is expected to be mined by ISL before accounting for recovery and plant yield.

Mine recovery rate of 70% is applied to account for losses for leaching solution not reaching and reacting with the ore body, as well as for non-recoverable saturated solution underground.

At this time a hydrological model has been built for the Fort Cady deposit, along with the installation of monitor wells. Pump tests on the monitor wells have been employed as a tool to locate additional faulting that could impact the mine design. A three-dimensional seismic survey of the deposit is planned for 2022 to further enhance clarity on strata and structural controls of the deposit for the mine design.

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14	PROCESSING AND RECOVERY METHODS

APBL has selected crystallization as the method for recovering boric acid (H₃BO₃). Crystallization has been selected because it’s an established process for purification of other industrial materials, can be operated on a continuous basis reducing equipment size, is based on fundamental physical properties such as relative solubility, and doesn’t require the use of flammable solvents.

The APBL processing plant is designed to operate continuously based on up-time of 87%. In order to produce 100,000 tons/yr of H₃BO₃. The plant will require 1,011 gal/min of pregnant leach solution (PLS) from the mine on a continuous basis. Other inputs for the process based on a production rate of 100 ktons/yr are 162 ktons/yr of 97% sulfuric acid (H₂SO₄), 13 ktons/yr of 35% hydrochloric acid (HCl), 140 gal/min of water, 50 MW of power, and 152 MM BTU/hr of natural gas. The plant will employ approximately 82 people at these production rates.

PLS that enters the plant will contain water, approximately 5% boric acid (H₃BO₃), calcium chloride (CaCl₂), trace metal salts, and any unused HCl from the mining operation. The solubility of H₃BO₃ is such that it will precipitate first if concentrated. A crystallization process is utilized to perform this concentration. The crystallizer operates at vacuum and at 180°F. Fluid enters the crystallizer on a continuous basis and is pumped around through a pump around heater. Steam is supplied to the heater to provide heat. During this crystallization process, 80% of the water present is boiled along with HCl. An overhead condenser supplied with cooling water is used to recover the water and HCl which is recycled for reuse in the mine. Due to the presence of unused HCl for the mining operation being sent through crystallization the process is constructed from acid resistant materials. These materials include acid resistant fiberglass composites, specialized alloys high in nickel and chromium, fluoropolymers, or rubber lined steel.

In particular, the crystallizer has been specified with a full vacuum pressure rating, 250°F temperature rating, and will be constructed of rubber lined steel. The pump around exchanger and overhead condenser have also been specified for full vacuum, 250°F and will be constructed from a specialized alloy high in nickel and chromium.

After crystallization, the resulting boric acid slurry contains boric acid crystals, calcium chloride (CaCl₂), trace metal salts, and trace hydrochloric acid. This slurry is filtered on a vacuum belt filter producing a H₃BO₃ wet cake and a liquid stream containing CaCl₂, trace metal salts, and trace HCl. The H₃BO₃ wet cake from the belt filter is dried in a tray dryer and loaded into 1-ton polymer sacks for sale.

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Liquid off the belt filter is sent to a HCl regeneration unit where lime is added to adjust pH to neutral. At neutral pH, any remaining HCl is converted to CaCl₂ eliminating the need for acid resistant material elsewhere in the process. Trace metal salts are also precipitated once pH is adjusted. These metal salts are filtered out utilizing a filter press.

The liquid off the filter press contains CaCl₂ which is converted into HCl and gypsum (CaSO₄) via a reaction with sulfuric acid (H₂SO₄). Gypsum has a low solubility, so it precipitates out. The resulting gypsum and aqueous HCl slurry are filtered on a vacuum belt filter. The aqueous HCl from the belt filter is recycled to the mining operation. Gypsum wet cake from the belt filter is dried for sale as a bulk product.

In addition to H₃BO₃ and gypsum, two other products could be produced as production volumes of H₃BO₃ increase. Sulfate of Potash (SOP) is being evaluated as a possible co-product. SOP is produced from a reaction between potash and H₂SO₄. This reaction also produces HCl which would be used for the mining operation. The potash and H2SO4 reaction is commonly referred to as the Mannheim Process and utilizes a furnace which can be purchased from vendors specializing in SOP equipment.

During the H₃BO₃ concentration in the crystallizer, lithium chloride (LiCl) is also concentrated. This LiCl remains in the liquid phase and could potentially be extracted prior to HCl regeneration. Extraction of lithium and production of lithium carbonate (LiCO₃) from this stream is currently being evaluated.

The QP believes the crystallization process is a technological and economically viable method of producing boric acid because it’s an established process for purification of other industrial materials, can be operated on a continuous basis reducing equipment size, is based on fundamental physical properties such as relative solubility, and doesn’t require the use of flammable solvents.

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15	INFRASTRUCTURE

The Project is located near Interstate-40 along with nearby access to rail and a natural gas transmission line. with nearby access to natural gas. Currently, the project is receiving electrical power from a 12kV powerline. Figure 15.1 shows general infrastructure needs for the Project.

Infrastructure required for the Project is expected to consist of the following:

•

Natural gas – FCCC will require a natural gas pipeline tied into the nearby transmission pipeline to provide heat for the processing plant.

•

Electrical power upgrade – an economic trade-off study is currently being conducted to evaluate co-generation and an upgraded powerline to the Project.

•

Rail – connection to a rail spur is being considered for the Project truck loading material from the plant to an existing rail spur location located 15 miles from the Project.

•

Roads – Plant access roads will require upgrades and some road may require paving. New access roads are also being considered.

•

Water – FCCC currently has adequate water wells for the Project. FCCC will need to building pipelines and install pumps to deliver water to the plant and mine sites.

•

Material storage – storage for materials (products and consumables) will need to be built near the plant site including a stacking system for gypsum.

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Figure 15.1 Fort Cady Project Infrastructure

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16	MARKET STUDIES

16.1

BORON MARKET

The global boron market is currently estimated to be valued at US$ 3.2 billion and consists of approximately 4.5Mtpa. Borates demand growth has had reasonably consistent compound annual growth rate (CAGR) of about 4% from 2013 through 2020. Traditional demand growth coupled with new applications are forecasted to increase demand growth to circa 6% CAGR from 2021 through 2028.

16.1.1

Boron Market

Traditional applications for boron include glass manufacturing (borosilicate glass and textile fiberglass), insulation, ceramics, specialty fertilizers and biocides for the agricultural industry, detergents, fire retardants, and wood preservatives (Figure 16.1. New applications for boron include its use for:

•

permanent magnets used in electric vehicles and re-chargeable electrical/battery equipment.

•

semi-conductors and electronics.

•

green energy/decarbonization in wind turbines, nuclear energy, and solar cells and

•

military vehicles & personal armor.

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Figure 16.1 Current Borates Demand by End Use

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The global boron market is dominated by two companies: Eti Maden (Turkish Govt- Owned); and Rio Tinto Borates (a subsidiary of Rio Tinto). Together, they supply approximately 80% of global boron market. Eti Maden alone supplies over 60% of the world market. Eti Maden appears to be the only producer with meaningful additional supply capacity.

The concentration of boron market reflects the rarity of economically viable borates deposits. There are only four main regions with large scale borate deposits: Anatolia (Turkey), California (USA), Central Andes (South America), and Tibet (Central Asia). Turkey has circa 73% of the world’s total boron reserves. The Fort Cady Project is the only permitted Boron resource that will add meaningful supply in the next five to seven years.

Over the ten years, leading through 2019, Rio Tinto Borates appears to have been operating at full capacity with approximately one million stpa of boric acid equivalent production. Production from Rio Tinto Borates decreased 7.7% in 2020 to 940 st of boric acid equivalent production and is forecasted to decline a further 4.0% in 2021. Rio Tinto Borates supplies approximately 70% of the US boron demand and this reduction in supply is resulting in higher prices and supply shortfalls. The five-year weighted average operating costs of Rio Tinto Borates were circa US$635/t with first half 2021 operating costs of US$650/t. The US market is APBL’s target market.

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16.1.2

Boron Pricing

In 2020, Rio Tinto received an average price of US$750/ton on a boric acid equivalent basis. Eti Maden average boric acid pricing is US$815/ton in 2021 and has recently announced price increases of between 3% and 4%. Since 2016, price for boric acid has steadily increased from US$767/ton to US$830/ton (US $915 metric tonne) in 2021 (Figure 16.2). Actual prices for boric acid are typically negotiated on short-term & long-term contracts between buyers and sellers.

Figure 16.2 Boron Pricing

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16.1.3

Boric Acid Specification

Boric acid technical grade specifications are as follows:

•

Chemical Specification:

•

Analyte Guarantee

•

B₂O₃%: 56.25 – 56.5

•

Equivalent H₃BO₃%: 99.9 – 100

•

SO₄ ppm: ≤250

•

Cl ppm: ≤10

•

Fe ppm: ≤4

•

Sieve Specification

•

U.S. Sieve Mesh Size (mm) % Retained Guarantee

•

No. 20, o.850mm ≤2.0

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16.2

LITHIUM MARKET

By 2017, prices had been propelled through successive multi year highs by strong demand from the Li-ion battery industry set against a backdrop of uncertainty over future supply. This attracted significant attention on the Li sector and incentivized investment into both mining and processing capacity. Prices for all Li products subsequently fell as production at operations in China, Australia, Canada, and Chile ramped-up, and as a swath of greenfield projects mitigated fears of future supply shortages.

Worldwide Lithium Carbonate equivalent production increased significantly from 38,000 mt in 2016 to 69,000 mt in 2017 and then to 95,000 mt in 2018. Lithium production retreated to 77,000 mt in 2019 and held steady through 2020. During the first half of 2020, the economic impact of the global COVID-19 pandemic resulted in substantial reduction on customer demand. During the second half of 2020, Li demand increased primarily due to strong growth in the Li-ion battery market.

16.2.1

Lithium Production

Lithium is extracted from brines that are pumped from beneath arid sedimentary basins and extracted from granitic pegmatite ores containing the mineral spodumene. Chile leads world production for Li and for production from brines. Australia leads production from pegmatites. Other potential sources for Li include clays, geothermal brines, oilfield brines, and zeolites. Owing to continued exploration, the USGS estimates a substantial increase in global resources of Li of 100 mt from a previous estimate of 39 mt in 2016. Currently five companies account for approximately two-thirds of the Li market: Albermarle, 18%; Ganfeng Lithium Co. Ltd., 17%; Sociedad Química y Minera de Chile (SQM), 14%; Tianqi Lithium Corp, 12%; and Livent Corp., 5%.

16.2.2

Pricing

Average annual lithium carbonate prices in 2016 were US$8,650/t. Lithium carbonate prices peaked in November 2017 at US$25,800/t. Since then, they have been under pressure, having fallen through much of 2018, 2019 and much of 2020. Table 16.3 shows annual lithium prices for the past six years. At the start of 2021, Lithium Carbonate equivalent spot prices were at US$4,786 and steadily increased to US$13,815 in July. At the end of July 2021 Lithium carbonate equivalent prices sharply increased with an average spot price for October 2021 at US$25,396 and that has peaked as high as US$28,688.

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Figure 16.3 Lithium Pricing

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16.3

POTASH

Potash is used primarily in the agricultural industry (~95%) as a source of soluble potassium in fertilizer but is also used in the manufacture of soap, glass, and ceramics. The two most common forms of potash are muriate of potash (MOP) which typically contains 60% KCl and sulfate of potash (SOP) containing K₂SO₄. MOP dominates the potash industry though SOP is becoming the preferred source of potassium due to many crops sensitivity to salt and SOP being an important source of sulfur in the form of soluble sulfate.

16.3.1

Production

Globally, the largest production of potash in descending order comes from Canada, Belarus, Russia, China, and Germany. The United States currently ranks ninth in production of potash. World potash capacity is projected to grow to 64 million tons in 2024 from 60 million tons in 2020. Since 2016, U.S. production has held around 500 thousand tons per year with imports ranging from 4.5 to 5.8 million tons over the past five years.

16.3.2

Pricing

Since 2017 MOP prices have fluctuated from US$276 to US$294 per ton with the exception of 2020 when the average price dipped to US$227/ton. 2020 prices most likely reflect market changes from the COVID-19 pandemic (Figure 16.4). SOP prices generally follow the same trend as MOP though at a premium. SOP prices have generally been in the US$700/ton since 2017. A factors that may affect potash pricing in the near term are the recent economic sanctions imposed on Belarus by the U.S and western Europe.

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Figure 16.4 MOP and SOP Pricing

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16.3.3

SOP Specification

•

Chemical Specification:

•

K₂O%: ³50

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S%: ³17

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Cl%: £0.8

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Particle Size Distribution, Cumulative % Retained


Tyler Mesh	Opening (mm)		Range (%)
4		4.76		0 - 8
5		4.00		10 - 8
6		3.36		35 - 59
8		2.38		80 - 94
10		1.68		98 - 100
12		1.41		97 - 100

•

Bulk Density lb/ft3: 80 – 85

•

Angle of Repose: 35°

16.4

GYPSUM

Gypsum is one of the most commonly used minerals in the world. In the U.S. most gypsum is used in the manufacturing of drywall and plaster for residential and commercial construction. Other common uses include as an additive to concrete, soil conditioning, and as a food/dietary additive.

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16.4.1

Production

The United States is the leading producer of mined crude gypsum (22 million tons), followed by Iran (16Mt) and China (15.5 Mt). Mined crude gypsum is currently mined in 16 states by 52 companies. Over the past five years, U.S. imports of gypsum have ranged from 4.3 to 6.1 million tons.

16.4.2

Pricing

Gypsum prices have fluctuated from US$33/ton in 2018 to US$40/ton in 2021 (Figure 16.5). 2021 prices reflect an increase of 11% from 2020. Demand for gypsum depends principally on construction industry activity. In recent years mined crude gypsum has competed with synthetic gypsum produced from flash generated from coal-fired generating stations. Synthetic gypsum production, however, is decreasing as more coal-fired stations are shut down or retired in favor of natural gas and renewable energy sources.

Figure 16.5 Gypsum Pricing

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16.5

CONTRACTS

There are currently no contracts or agency agreements for boron, lithium, potash, or gypsum at this time for the Project. FCCC does not have any contracts at this time for mining, concentrating, processing, refining, transporting, hedging, and has no forward sales contracts. At this time, the company has not determined which of the above contracts will be required.

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16.6

MARKET ENTRY STRATEGY

FCCC intends to approach potential strategic partners for different end-market segments for the products. The company has entered into non-binding Letter of Interest agreements with Borman LLC and Compass Minerals Inc. and intends to enter into commercial and technical agreements with strategic partners and customers as the project is developed.

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17	ENVIRONMENTAL STUDIES, PERMITTING AND PLANS, NEGOTIATIONS, OR AGREEMENTS WITH LOCAL INDIVIDUALS OR GROUPS

FCCC currently has the following permits in place:

Air Permit – All processes currently identified have been permitted by Mojave Desert Air Quality Control District (MDAQCD) for up to 270,000 tons per year (tpy) Boric Acid and 80,000 tpy SOP. The permits have been renewed annually by paying the annual fee. Any modifications to process equipment or use of process equipment will require a modification to the existing permit. All modifications must meet national ambient air quality standards and MDAQMD requirements.

Water Permits – The project has been operating under a Water Quality Permit issued by the Lahontan Regional Water Quality Control Board (LRWQCB) in 1988. The permit includes all surface impoundments associated with the boric acid pilot plant and requires post mining rinsing and monitoring. FCCC remains compliant with the permit by sampling water well DHB-1 quarterly and submitting quarterly reports. A Final Permanent Closure Plan has been submitted to LRWQCB for closure of the existing ponds. FCCC and LRWQCB have agreed to close the ponds if LRWQCB will close the permit.

Stormwater – The project has received a Notice of Non-applicability (NONA), documenting that the project does not require a stormwater permit for either construction or operations. The NONA was issued as the project is in a closed basin with no stormwater discharge.

San Bernardino County Land Use Planning issued the Mining and Reclamation Permit in 1994, based upon the 1990 Plan of Operations (PoO) and subsequent Environmental Impact Report (EIR). The PoO was amended, and the permit modified in 2019 to address changes such as moving the plant location, eliminating a rail crossing I-40 and including additional rights to water. The Fort Cady Project is not located within a water district with adjudicated water rights. Therefore, water rights are granted by San Bernardino County through the Mining & Reclamation Permit. The Mining and Reclamation Permit includes Condition of Approval requirements for engineering and planning, as well as requirements to eliminate impacts to desert tortoises.

The BLM issued a Record of Decision (ROD) in 1994 and approved the EIS/EIR boundary (noted on Figure 3.2). the ROD authorizes mining borates at a rate of 90,000 tpy. The ROD also has requirements for company activities to eliminate adverse impacts to desert tortoises and cultural resources. FCCC will be updating the Plan of Operations to 270,000 tpy, which will require an update to the permit. FCCC has filed an updated PoO which is currently in the review process.

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The Underground Injection Control (UIC) permit administered by the U.S. Environmental Protection Agency (EPA). FCCC is currently modifying this permit and is in the process of adding additional monitor wells that demonstrate that U.S. drinking water aquifers (USDW) are not degraded by ISL activities. FCCC will also be required to perform a series of tests on the first 5 Injection/Recovery wells out of each group of 40 wells to confirm the historical demonstrated permeability of 1 X 10^-9 d is accurate.

Additional permitting that will likely be required for the project includes:

A financial assurance cost estimate (FACE), a surface disturbance bond, will need to be updated for all new equipment, buildings, and ground disturbance. The County conducts their annual inspection around Christmas each year. FCCC is required to update the FACE at that time. If construction is starts in January, then the FACE should be updated and posted at that time.

The California Unified Control Act/Agency (CUPA) has primacy over EPA’s Tier II reporting requirements. Once the chemical inventory is finalized it can be filed online.

An EPA ID will be requested when waste streams have been finalized. This number is issued by the State of California Department of Toxic Substance Control (DTSC).

FCCC will need to obtain building permits from San Bernardino County prior to construction.

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18	CAPITAL AND OPERATING COSTS

There are no operating or capital costs to report at this time. Engineering and construction are progressing for the SSBF. Once operational, the SSBF should provide many of the necessary parameters for determining operating and capital costs for initial production of 90 kstpa boric acid and 80 kstpa SOP.

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19	ECONOMIC ANALYSIS

A current high-level economic analysis has been prepared to support the mineral resource estimation. Key assumptions used in the economic assessment include; ISL mining operation delivering 5% boric acid in solution to an above ground processing plant; operating costs of $587 per tonne of boric acid produced; 92% conversion of boric acid in solution to saleable boric acid powder (recovery rate); 80% recovery of in-situ boron (extraction ratio) and an average sales price of US$900 per tonne of boric acid. A high level financial model using a discount rate of 8% delivered a positive net present value to support the cut-off grade and more broadly the resulting mineral resource estimation. Potential by-product production of lithium, SOP and gypsum has been excluded from the financial model and may ultimately provide the potential for a reduction in the cut-off grade.

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20	ADJACENT PROPERTIES

Elementis operates the Hectorite Mine adjacent to the west side of the Fort Cady Project. The mine produces hectorite, a specialty clay mineral used in ceramics, cosmetics, and other specialties requiring high viscosity or high thermal stability. While the mine is adjacent to the Fort Cady Project it produces a product that does not compete with borate, Li, or other possible by-products being considered by APBL. APBL through its subsidiary, FCCC does have a mineral lease agreement with Elementis for certain unpatented mining claims.

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21	OTHER RELEVANT DATA AND INFORMATION

There is no other relevant information or data to present at this time.

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22	INTERPRETATION AND CONCLUSIONS

APBL has an established mineral holding 4,910 acres through ownership of fee lands, unpatented placer claims, and a mineral lease agreement. The property has undergone past exploration primarily conducted in the 1980’s along with more recent drilling conducted in 2017 which validated previous exploration and expanded known mineral occurrences. Drilling completed on the Project can be considered sufficient for the delineation of a mineral resource estimate.

Exploration drilling has led to a geologic interpretation of the deposit as lacustrine evaporite sediments containing colemanite, a hydrated calcium borate mineral. The deposit also contains appreciable quantities of Li though the source mineral for Li has not been identified at this time. Geologic modeling based on drilling and sampling results depicts an elongate deposit of lacustrine evaporite sediments containing colemanite. The deposit is approximately a 2.1 mi. long by 0.6 mi. wide and ranging in thickness from 70 to 262 ft. mineralization has been defined in four distinct horizons defined by changes in lithology and B2O3 analyses.

A mineral resource has been estimated and reported using a cut-off grade of 5% B₂O₃. Measured plus Indicated resources for the Project are 97.55 Mt with a grade of 6.53% for B₂O₃ and 324 ppm for Li. Much of the interpretation and mineral resource estimations were derived through a gridded model created from drilling and sampling data using Vulcan modeling software. Additional review and estimations of the model were conducted using Carlson Mining software. The details of the methodology are described in the report text.

The QP concludes that there are reasonable prospects for economic extraction for the mineral resource estimated and presented in this Initial Assessment. APBL has been diligent in validating the work completed by the previous operators and further expanding the size and classification assurance of the deposit. Current and previous evaluations of mining methods indicate a deposit well suited for ISL solution mining as a potential method for economic extraction. Metallurgical testing and process engineering indicate economic potential as well. APBL is currently having additional engineering and testing work performed to refine dissolution/recovery rates and wellfield design. In addition, the SSBF

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will provide parameters leading toward designing a processing facility. Additional studies that include detailed mine planning, geotechnical and hydrologic evaluations, full market studies and economic evaluations will need to be performed. Based on this, the viability of the deposit for demonstrated economic feasibility has yet to be determined. APBL has announced in a press release (October 13,2021) of advancing and targeting a Feasibility Study in the second quarter 2022.

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23	RECOMMENDATIONS

Millcreek considers the Fort Cady Borate Project to be of sufficient merit to recommend proceeding with project development of 90 kstpa production facility. The QP makes the following recommendations to advance the geology and resource characteristics for the Project:

The current resource estimate classifies approximately 10.5% of the estimate as Inferred resources and approximately 56% of the total resource is classified as Indicated resources. Additional delineation drilling will further refine resource classification, adding more tonnage to Measured from Indicated and from the Inferred to Indicated resource categories. Figure 23.1 shows 11 proposed drilling locations that should significantly increase Measured resources from Indicated classification. The QP has also located four drilling locations in Section 36 to further test resource potential on the southern land holdings held by APBL. The all-in cost per drill hole (access and pad preparation, drilling, sampling, analyses, permitting, and geologic support) is approximately $121,092. The proposed drilling program has an estimated budget of $1,816,386 (Table 23.1).

Table 23.1Recommended Drilling Budget


Item	Per Hole		15 Holes
Drilling		61,500		922,500
Access/Pad Preparation		25,000		375,000
Geologic Support		12,000		180,000
Sampling/Analysis		2,250		33,750
Permittin/Clearance		4,667		70,000
Mobilization/Demobilizatio		4,667		70,000
Contingency @ 10%		11,008		165,125

Total	$	121,092	$	1,816,375

With any future drilling, the QP recommends using a standardized sample length of one or two meters. Sample lengths with past drilling has varied from 0.1 m. to 5.9 m. in the mineralized horizons. there is sufficient knowledge from previous drilling to determine horizon breaks and a standardized sample length will reduce sampling and analytical costs.

The deposit holds significant quantities of Li. Little is known at this time about which mineral(s) host Li and whether Li is recovered in appreciable quantities through ISL. Additional mineralogical testing should be done to identify the source for Li such scanning electron microprobe or QEMSCAN. Further testing should be done on PLS to determine how much Li is leached and what processes might be required to extract Li and steps to produce lithium carbonate LiCO3 and/or lithium hydroxide (LiOH (H₂O)n).

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APBL should consider using seismic and electromagnetic surveying to gain further understanding of the structural setting of the Project and may assist in identifying facies changes in the sediments. Further understanding of faulting can assist in understanding permeability and flow for solution mining.

As the project moves forward, further analysis should be completed to determine if economics will support a lower cut-off grade for B₂O₃. A lower cut-off grade could significantly increase mineral resources and in the future, mineral reserves. Dissolution testing should help determine recovery of boric acid and the SSBF should identify associated costs of recovering boric acid at lower cut-off grades. For instance, lowering the cut-off grade to 2.5% B₂O₃, yields 240.1 Mt with an average grade of 4.92% B₂O₃%.

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24	REFERENCES

Agapito Associates, Inc., 2021. Draft Conceptual Engineering Study Report, prepared for American Pacific Borates Ltd.

ASX Announcement, 2021. ABR Advancing Value Engineering Program for Fort Cady Integrated Boron Facility, Press Release, October 13, 2021.

Bartlett, R.W., 1998. Solution Mining: Leaching and Fluid Recovery of Materials, Second Edition, Routledge Publishing.

Burns, C., 2021. Situation Report Environmental Permitting, Rev. 9, FCCC Internal Report, Aug. 15, 2021.

Confluence Water Resources LLC, 2019. Fault B Technical Report, Fort Cady Project, San Bernardino County. Prepared for American Pacific Borate Ltd., March 2019.

Core Laboratories, 1980. Core Analysis. Prepared for Duval Corporation, November 1980.

Dames & Moore, 1993. Fort Cady Mineral Corporation Solution Mining Project, Final Environmental Impact Statement. Environmental Impact Report. Prepared for U.S. Department of the Interior, Bureau of Land Management and County of San Bernardino, December 1993.

Dibblee, T, 1967. Areal Geology of the Western Mojave Desert, California; US Department of the Interior Geological Survey Professional Paper 522

Duval, 1983. Fort Cady Borate Computerized Ore Reserve Calculations, Review for NL Industries. Duval Corporation, November 1983.

In-Situ Inc., 1990. Fort Cady Injection Test. Prepared for Mountain States Mineral Enterprises Inc.. April 1990.

McGinley & Associates, 2020. Numerical Groundwater Flow Model Report, Fort Cady Project, San Bernardino County, California. Prepared for American Pacific Borate Ltd., April 2020.

Fourie, L, 2018. Updated JORC Compliant Mineral Resource Estimation for the Fort Cady Project, San Bernardino County, California. Prepared for American Pacific Borate Ltd., December 2018.

Respec Company LLC, 2021. American Pacific Borate SEC SK-1300 Report (draft).

Respec Company LLC, 2021. Enhanced Definitive Feasibility Study, Section 2.0 Ore Reserve Estimation. Pages 6 – 12.

Shaw and Partners Ltd., 2021. ABR Equity Report, August 2021.

Stirrett, T., 2021. External Memorandum, Summary of RESPEC Work

Simon Hydro-Search, 1993. Fort Cady Mineral Corporation Solution Mining Project Feasibility Report, San Bernardino County, California. Prepared for Southern California Edison by Simon Hydro-Search. October 22, 1993.

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Trading Economics, 2021. Lithium Markets. Accessed October 13, 2021. https://tradingeconomics.com/commodity/lithium

Wilkinson & Krier, 1985. Geological Summary – Duval Corp. internal review, by P Wilkinson and Krier N, Jan 1985.

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25	RELIANCE ON INFORMATION PROVIDED BY THE REGISTRANT

APBL has provided the QP with a large variety of materials for the preparation of this report. These materials include the following:

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Drilling records from the 2017 drilling program completed by APBL in 2017 including drilling locations, drill logs, sampling records, analytical results/certificates, geophysical logs, and core photos.

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Drilling records from Duval and FCMC including drill logs, sampling records, analytical results/certificates, and geophysical logs.

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Historical drilling maps and testing records.

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Agapito Conceptual Engineering Study.

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Various sections to the Initial Study and Second Study prepared by Respec.

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Land records, land maps, and land purchase agreements showing property holdings of FCCC.

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Geologic Model prepared by TMS including grid files and data input files.

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Copies of recent APBL press releases

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