Multiple Wide, High-Grade Intercepts at the CV5 Pegmatite, including 153.8 m at 2.00% Li2O, Completes Drill Dataset for Upcoming Feasibility Study and Ore Reserve in Q3-2025

________________
¹ Shaakichiuwaanaan (CV5 & CV13) Mineral Resource Estimate (80.1 Mt at 1.44% Li2O and 163 ppm Ta2O5 Indicated, and 62.5 Mt at 1.31% Li2O and 147 ppm Ta2O5 ppm Inferred) is reported at a cut-off grade of 0.40% Li2O (open-pit), 0.60% Li2O (underground CV5), and 0.80% Li2O (underground CV13) with an Effective Date of August 21, 2024 (through drill hole CV24-526). Mineral Resources are not Mineral Reserves as they do not have demonstrated economic viability.

Hole ID

Substrate

Total Depth (m)

Azimuth
(°)

Dip
(°)

Easting

Northing

Elevation
(m)

Core Size

Cluster

CV24-643

Water

394.9

160

-55

570074.0

5930705.6

371.7

NQ

CV5

CV24-648

Land

484.9

180

-48

572564.4

5931724.7

374.6

NQ

CV5

CV24-663

Water

215.0

160

-60

570784.8

5930905.2

371.8

NQ3

CV5

CV24-667

Land

529.9

179

-58

572564.7

5931725.3

374.6

NQ

CV5

CV24-668

Land

254.0

158

-45

569410.0

5930345.5

389.3

NQ

CV5

CV24-669

Land

281.0

158

-45

569965.3

5930554.4

376.3

NQ

CV5

CV24-671

Land

209.0

160

-45

569762.7

5930394.7

380.1

NQ

CV5

CV24-674

Land

545.5

150

-50

571673.2

5931541.5

396.8

NQ

CV5

CV24-675

Land

490.9

145

-72

572151.5

5931550.8

375.9

NQ

CV5

CV24-676

Land

207.5

145

-65

570036.3

5930783.1

377.8

NQ

CV5

CV24-677

Land

347.0

235

-60

569963.3

5930554.0

376.4

NQ

CV5

CV24-678

Land

299.1

158

-46

569504.8

5930370.1

383.3

NQ

CV5

CV24-679

Water

125.0

340

-60

570814.8

5931002.4

372.0

NQ3

CV5

CV24-680

Land

226.9

158

-45

569841.2

5930331.4

377.6

NQ

CV5

CV24-681

Water

494.0

0

-90

572438.5

5931450.0

372.1

NQ

CV5

CV24-682

Land

362.0

160

-48

570646.9

5931010.2

373.7

NQ

CV5

CV24-683

Land

512.0

163

-56

572564.8

5931726.3

374.6

NQ

CV5

CV24-684

Water

161.0

27

-60

570932.4

5930996.7

371.9

NQ3

CV5

CV24-685

Land

299.0

160

-80

569743.0

5930442.0

379.2

NQ

CV5

CV24-686

Land

209.0

160

-45

570249.5

5930646.4

384.3

NQ

CV5

CV24-687

Land

503.0

134

-62

572151.7

5931551.1

375.9

NQ

CV5

CV24-688

Water

344.1

152

-45

570832.5

5931093.5

371.9

NQ

CV5

CV24-689

Land

167.0

11

-51

569705.4

5930476.0

380.2

NQ3

CV5

CV24-690

Land

115.8

160

-45

569799.1

5930303.3

376.4

NQ

CV5

CV24-691

Water

371.3

158

-46

572275.8

5931522.4

372.9

NQ

CV5

CV24-692

Land

272.1

158

-75

570317.9

5930621.6

383.0

NQ

CV5

CV24-693

Land

344.0

125

-45

570647.6

5931010.5

373.8

NQ

CV5

CV24-694

Land

443.5

160

-48

571672.8

5931541.1

396.8

NQ

CV5

CV24-695

Land

343.9

310

-70

569965.8

5930425.6

377.0

NQ

CV5

CV24-697

Water

322.9

158

-45

570707.1

5930992.2

371.9

NQ

CV5

CV24-698

Water

265.9

160

-59

572263.5

5931404.1

373.0

NQ

CV5

CV24-699

Land

409.7

150

-58

572151.3

5931550.9

375.9

NQ

CV5

CV24-700

Land

302.1

163

-45

569453.6

5930438.9

380.5

NQ

CV5

CV24-701

Land

471.6

157

-59

571947.8

5931540.9

380.7

NQ

CV5

CV24-702

Land

302.2

170

-50

571561.1

5931282.3

374.5

NQ

CV5

CV24-703

Land

450.0

154

-50

571708.1

5931460.6

378.6

NQ

CV5

CV24-704

Land

355.0

200

-50

571097.9

5931094.0

375.2

NQ

CV5

CV24-705

Land

407.2

167

-73

570110.2

5930638.0

377.0

NQ

CV5

CV24-706

Water

203.0

160

-45

571582.3

5931171.8

372.2

NQ

CV5

CV24-707

Water

287.1

162

-48

570707.9

5930989.2

373.5

NQ

CV5

CV24-708

Land

431.0

160

-61

572052.0

5931534.6

372.6

NQ

CV5

CV24-709

Land

320.3

155

-73

571442.8

5931177.7

377.0

NQ

CV5

CV24-710

Water

275.0

185

-55

571586.6

5931171.8

373.0

NQ

CV5

CV24-711

Land

236.5

162

-63

571561.2

5931282.6

374.4

NQ

CV5

CV24-711A

Land

368.0

162

-63

571560.9

5931282.6

374.4

NQ

CV5

CV24-712

Land

371.1

150

-45

571616.1

5931411.0

375.6

NQ

CV5

CV24-713

Water

161.2

175

-50

571509.5

5931133.2

373.0

NQ

CV5

CV24-714

Land

449.1

159

-51

571947.9

5931540.8

380.9

NQ

CV5

CV24-715

Water

317.1

150

-46

570511.7

5930943.5

373.0

NQ

CV5

CV24-716

Water

145.9

158

-45

571371.3

5931036.7

373.0

NQ

CV5

CV24-717

Land

353.0

167

-45

570110.3

5930637.3

377.0

NQ

CV5

CV24-718

Land

425.0

148

-59

572052.2

5931534.7

372.7

NQ

CV5

CV24-719

Land

305.0

158

-53

571132.6

5931145.0

376.3

NQ

CV5

CV24-720

Water

117.9

158

-70

571371.3

5931037.1

372.9

NQ

CV5

CV24-721

Land

402.8

142

-47

571616.4

5931411.0

375.4

NQ

CV5

CV24-722

Water

137.0

158

-45

571097.7

5930963.1

373.0

NQ

CV5

CV24-723

Water

95.1

158

-45

570575.5

5930788.3

373.0

NQ

CV5

CV24-724

Land

356.1

152

-58

572011.7

5931467.0

375.7

NQ

CV5

CV24-725

Land

503.0

155

-65

571311.7

5931087.6

380.0

NQ

CV5

CV24-726

Water

97.8

158

-45

570998.1

5930944.0

373.0

NQ

CV5

CV24-727

Land

446.9

146

-63

572052.3

5931534.8

372.7

NQ

CV5

CV24-728

Water

83.1

158

-45

570667.0

5930827.1

373.0

NQ

CV5

CV24-730

Land

305.0

160

-55

571336.9

5931165.8

375.9

NQ

CV5

CV24-731

Water

101.1

158

-45

570899.1

5930925.1

373.0

NQ

CV5

CV24-732

Water

268.9

158

-58

572212.3

5931385.5

373.0

NQ

CV5

CV24-733

Land

392.2

145

-63

571561.7

5931282.9

374.5

NQ

CV5

CV24-734

Water

122.0

158

-45

570847.3

5930912.0

373.0

NQ

CV5

CV24-735

Land

404.2

155

-51

571653.2

5931324.2

376.8

NQ

CV5

CV24-736

Land

383.1

158

-56

572214.1

5931534.1

373.2

NQ

CV5

CV24-737

Water

415.8

170

-62

572324.5

5931536.8

373.0

NQ

CV5

CV24-738

Water

119.0

160

-45

571292.1

5931011.9

373.0

NQ

CV5

CV24-739

Land

401.0

158

-55

568598.9

5930071.1

388.9

NQ

CV5

CV24-740

Land

536.1

125

-60

571312.4

5931088.5

380.1

NQ

CV5

CV24-741

Land

496.5

170

-64

572051.9

5931534.5

372.6

NQ

CV5

CV24-742

Land

509.8

188

-47

572565.1

5931727.7

373.7

NQ

CV5

CV24-743

Water

85.8

158

-50

571497.3

5931041.6

372.9

NQ

CV5

CV24-744

Water

196.9

158

-45

571570.8

5931124.5

373.0

NQ

CV5

CV24-745

Land

515.2

175

-80

572213.8

5931534.5

373.3

NQ

CV5

CV24-746

Land

369.2

158

-60

571977.8

5931451.6

376.5

NQ

CV5

CV24-748

Water

386.0

155

-58

572324.9

5931538.5

372.1

NQ

CV5

CV24-749

Land

305.0

158

-65

568474.2

5930093.9

399.8

NQ

CV5

CV24-750

Water

443.0

160

-70

571220.1

5930923.9

372.8

NQ

CV5

CV24-751

Land

431.0

150

-85

571286.3

5930893.2

377.4

NQ

CV5

CV24-752

Land

494.1

159

-48

569965.8

5930738.0

376.0

NQ

CV5

CV24-753

Water

345.6

175

-75

572328.8

5931537.4

373.4

NQ

CV5

CV24-755

Land

536.0

194

-51

572564.8

5931727.8

373.6

NQ

CV5

CV24-756

Land

253.9

158

-45

568474.5

5930093.4

399.7

NQ

CV5

CV24-758

Land

506.1

145

-75

572213.9

5931534.8

373.2

NQ

CV5

CV24-759

Land

93.0

158

-45

568479.6

5929966.6

388.9

NQ

CV5

CV24-760

Water

428.0

115

-75

571080.9

5930873.1

373.0

NQ

CV5

CV24-764

Land

77.0

158

-65

568479.8

5929966.0

388.8

NQ

CV5

CV24-765

Water

358.9

0

-90

572445.5

5931369.9

373.4

NQ

CV5

CV24-766

Land

90.0

158

-45

568433.9

5929939.3

391.1

NQ

CV5

CV24-767

Land

326.0

159

-60

569819.4

5930506.5

375.4

NQ

CV5

CV24-769

Land

374.0

170

-68

571579.6

5931234.4

374.9

NQ3

CV5

CV24-777

Land

101.1

340

-75

568849.3

5930131.6

395.1

NQ3

CV5

CV24-781

Land

200.1

330

-85

569283.5

5930125.5

388.4

NQ3

CV5

CV24-783

Land

416.0

145

-67

571927.4

5931447.3

377.6

NQ3

CV5

Criteria

JORC Code explanation

Commentary

Sampling techniques

• Nature and quality of sampling (eg cut channels, random chips, or specific specialized industry standard measurement tools appropriate to the minerals under investigation, such as down hole gamma sondes, or handheld XRF instruments, etc). These examples should not be taken as limiting the broad meaning of sampling.
• Include reference to measures taken to ensure sample representivity and the appropriate calibration of any measurement tools or systems used.
• Aspects of the determination of mineralization that are Material to the Public Report.
• In cases where 'industry standard' work has been done this would be relatively simple (eg 'reverse circulation drilling was used to obtain 1 m samples from which 3 kg was pulverized to produce a 30 g charge for fire assay'). In other cases more explanation may be required, such as where there is coarse gold that has inherent sampling problems. Unusual commodities or mineralization types (eg submarine nodules) may warrant disclosure of detailed information.

• Core sampling protocols meet industry standard practices.
• Core sampling is guided by lithology as determined during geological logging (i.e., by a geologist). All pegmatite intervals are sampled in their entirety (half-core), regardless if spodumene mineralization is noted or not (in order to ensure an unbiased sampling approach) in addition to ~1 to 3 m of sampling into the adjacent host rock (dependent on pegmatite interval length) to "bookend" the sampled pegmatite.
• The minimum individual sample length is typically 0.5 m and the maximum sample length is typically 2.0 m. Targeted individual pegmatite sample lengths are 1.0 to 1.5 m.
• All drill core is oriented to maximum foliation prior to logging and sampling and is cut with a core saw into half-core pieces, with one half-core collected for assay, and the other half-core remaining in the box for reference.
• Core samples collected from drill holes were shipped to SGS Canada's laboratory in Val-d'Or, QC, or Radisson, QC, for sample preparation (code PRP90 special) which included drying at 105°C, crush to 90% passing 2 mm, riffle split 250 g, and pulverize 85% passing 75 microns. Core sample pulps were shipped by air to SGS Canada's laboratory in Burnaby, BC, where the samples were homogenized and subsequently analyzed for multi-element (including Li and Ta) using sodium peroxide fusion with ICP-AES/MS finish (codes GE_ICP91A50 and GE_IMS91A50).

Drilling techniques

• Drill type (eg core, reverse circulation, open-hole hammer, rotary air blast, auger, Bangka, sonic, etc) and details (eg core diameter, triple or standard tube, depth of diamond tails, face-sampling bit or other type, whether core is oriented and if so, by what method, etc).

• Holes are NQ or NQ3 size core diamond drilling with Core was not oriented.

Drill sample recovery

• Method of recording and assessing core and chip sample recoveries and results assessed.
• Measures taken to maximize sample recovery and ensure representative nature of the samples.
• Whether a relationship exists between sample recovery and grade and whether sample bias may have occurred due to preferential loss/gain of fine/coarse material.

• All drill core was geotechnically logged following industry standard practices, and include TCR, RQD, ISRM, and Q-Method. Core recovery is very good and typically exceeds 90%.

Logging

• Whether core and chip samples have been geologically and geotechnically logged to a level of detail to support appropriate Mineral Resource estimation, mining studies and metallurgical studies.
• Whether logging is qualitative or quantitative in nature. Core (or costean, channel, etc) photography.
• The total length and percentage of the relevant intersections logged.

• Upon receipt at the core shack, all drill core is pieced together, oriented to maximum foliation, metre marked, geotechnically logged (including structure), alteration logged, geologically logged, and sample logged on an individual sample basis. Core box photos are also collected of all core drilled, regardless of perceived mineralization. Specific gravity measurements of pegmatite are also collected at systematic intervals for all pegmatite drill core using the water immersion method, as well as select host rock drill core. 
• The logging is qualitative by nature, and includes estimates of spodumene grain size, inclusions, and model mineral estimates. 
• These logging practices meet or exceed current industry standard practices.

Sub-sampling techniques and sample preparation

• If core, whether cut or sawn and whether quarter, half or all core taken.
• If non-core, whether riffled, tube sampled, rotary split, etc and whether sampled wet or dry.
• For all sample types, the nature, quality and appropriateness of the sample preparation technique.
• Quality control procedures adopted for all sub-sampling stages to maximize representivity of samples.
• Measures taken to ensure that the sampling is representative of the in situ material collected, including for instance results for field duplicate/second-half sampling.
• Whether sample sizes are appropriate to the grain size of the material being sampled.

• Drill core sampling follows industry best practices. Drill core was saw-cut with half-core sent for geochemical analysis and half-core remaining in the box for reference. The same side of the core was sampled to maintain representativeness. 
• Sample sizes are appropriate for the material being assayed.
• A Quality Assurance / Quality Control (QAQC) protocol following industry best practices was incorporated into the program and included systematic insertion of quartz blanks and certified reference materials (CRMs) into sample batches at a rate of approximately 5% each. Additionally, analysis of pulp-split duplicates was completed to assess analytical precision, and external (secondary) laboratory pulp-split duplicates were prepared at the primary lab for subsequent check analysis and validation at a secondary lab.
• All protocols employed are considered appropriate for the sample type and nature of mineralization and are considered the optimal approach for maintaining representativeness in sampling.

Quality of assay data and laboratory tests

• The nature, quality and appropriateness of the assaying and laboratory procedures used and whether the technique is considered partial or total.
• For geophysical tools, spectrometers, handheld XRF instruments, etc, the parameters used in determining the analysis including instrument make and model, reading times, calibrations factors applied and their derivation, etc.
• Nature of quality control procedures adopted (eg standards, blanks, duplicates, external laboratory checks) and whether acceptable levels of accuracy (ie lack of bias) and precision have been established.

• Core samples collected from drill holes were shipped either to SGS Canada's laboratory in Val-d'Or, QC, or Radisson, QC for standard sample preparation (code PRP90 special) which included drying at 105°C, crush to 90% passing 2 mm, riffle split 250 g, and pulverize 85% passing 75 microns. Core sample pulps were shipped by air to SGS Canada's laboratory in Burnaby, BC, where the samples were homogenized and subsequently analyzed for multi-element (including Li and Ta) using sodium peroxide fusion with ICP-AES/MS finish (codes GE_ICP91A50 and GE_IMS91A50).
• The Company relies on both its internal QAQC protocols (systematic use of blanks, certified reference materials, and external checks), as well as the laboratory's internal QAQC.
• All protocols employed are considered appropriate for the sample type and nature of mineralization and are considered the optimal approach for maintaining representativeness in sampling.

Verification of sampling and assaying

• The verification of significant intersections by either independent or alternative company personnel.
• The use of twinned holes.
• Documentation of primary data, data entry procedures, data verification, data storage (physical and electronic) protocols.
• Discuss any adjustment to assay data.

• Intervals are reviewed and compiled by the VP Exploration and Project Managers prior to disclosure, including a review of the Company's internal QAQC sample analytical data.
• Data capture utilizes MX Deposit software whereby core logging data is entered directly into the software for storage, including direct import of laboratory analytical certificates as they are received. The Company employs various on-site and post QAQC protocols to ensure data integrity and accuracy.
• Adjustments to data include reporting lithium and tantalum in their oxide forms, as it is reported in elemental form in the assay certificates. Formulas used are Li₂O = Li x 2.153, and Ta₂O₅ = Ta x 1.221.

Location of data points

• Accuracy and quality of surveys used to locate drill holes (collar and down-hole surveys), trenches, mine workings and other locations used in Mineral Resource estimation.
• Specification of the grid system used.
• Quality and adequacy of topographic control.

• Each drill hole's collar has been surveyed with a RTK Trimble Zephyr 3 or Topcon GR-5, with small number of holes by average handheld GPS.
• The coordinate system used is UTM NAD83 Zone 18.
• The Company completed a property-wide LiDAR and orthophoto survey in August 2022, which provides high-quality topographic control.
• The quality and accuracy of the topographic controls are considered adequate for advanced stage exploration and development, including mineral resource estimation.

Data spacing and distribution

• Data spacing for reporting of Exploration Results.
• Whether the data spacing and distribution is sufficient to establish the degree of geological and grade continuity appropriate for the Mineral Resource and Ore Reserve estimation procedure(s) and classifications applied.
• Whether sample compositing has been applied.

• At CV5, drill hole collar spacing is dominantly grid based. Several collars are typically completed from the same pad at varied orientations targeting pegmatite pierce points of ~50 (Indicated) to 100 m (Inferred) spacing.
• At CV13, drill hole spacing is dominantly grid based, targeting ~100 m pegmatite pierce points; however, collar locations and hole orientations may vary widely, which reflect the varied orientation of the pegmatite body along strike.
• At CV9, drill hole collar spacing is irregular with varied hole orientations and multiple collars on the same pad.
• It is interpreted that the large majority of the drill hole spacing at each pegmatite is sufficient to support a mineral resource estimate.
• Core sample lengths typically range from 0.5 to 2.0 m and average ~1.0 to 1.5 m. Sampling is continuous within all pegmatite encountered in the drill hole.

Orientation of data in relation to geological structure

• Whether the orientation of sampling achieves unbiased sampling of possible structures and the extent to which this is known, considering the deposit type.
• If the relationship between the drilling orientation and the orientation of key mineralized structures is considered to have introduced a sampling bias, this should be assessed and reported if material.

• No sampling bias is anticipated based on structure within the mineralized body. 
• The principal mineralized bodies are relatively undeformed and very competent, although have meaningful structural control.
• At CV5, the principal mineralized body and adjacent lenses are steeply dipping resulting in oblique angles of intersection with true widths varying based on drill hole angle and orientation of pegmatite at that particular intersection point. i.e., the dip of the mineralized pegmatite body has variations in a vertical sense and along strike, so the true widths are not always apparent until several holes have been drilled (at the appropriate spacing) in any particular drill-fence.
• At CV13, the principal pegmatite body has a shallow varied strike and northerly dip.
• At CV9, the orientation and geometry of the pegmatite is not well understood. The pegmatite is currently interpreted to be comprised of a single principal dyke, which outcrops at surface, has a steep northerly dip, and is moderately plunging to the east-southeast.

Sample security

• The measures taken to ensure sample security.

• Samples were collected by Company staff or its consultants following specific protocols governing sample collection and handling. Core samples were bagged, placed in large supersacs for added security, palleted, and shipped directly to Val-d'Or, QC, or Radisson, QC, being tracked during shipment along with Chain of Custody. Upon arrival at the laboratory, the samples were cross-referenced with the shipping manifest to confirm all samples were accounted for. At the laboratory, sample bags are evaluated for tampering.

Audits or reviews

• The results of any audits or reviews of sampling techniques and data.

• A review of the sample procedures for the Company's 2021 fall drill program (CF21-001 to 004) and 2022 winter drill program (CV22-015 to 034) was completed by an Independent Competent Person and deemed adequate and acceptable to industry best practices (discussed in a technical report titled "NI 43-101 Technical Report on the Corvette Property, Quebec, Canada", by Alex Knox, M.Sc., P.Geol., Issue Date of June 27^th, 2022.)
• A review of the sample procedures through the Company's 2024 winter drill program (through CV24-526) was completed by an independent Competent Person with respect to the Shaakichiuwaanaan's Mineral Resource Estimate (CV5 & CV13 pegmatites) and deemed adequate and acceptable to industry best practices (discussed in a technical report titled "NI 43–101 Technical Report, Preliminary Economic Assessment for the Shaakichiuwaanaan Project, James Bay Region, Quebec, Canada" by Todd McCracken, P.Geo., Hugo Latulippe, P.Eng., Shane Ghouralal, P.Eng., MBA, and Luciano Piciacchia, P.Eng., Ph.D., of BBA Engineering Ltd., Ryan Cunningham, M.Eng., P.Eng., of Primero Group Americas Inc., and Nathalie Fortin, P.Eng., M.Env., of WSP Canada Inc., Effective Date of August 21, 2024, and Issue Date of September 12, 2024.
• Additionally, the Company continually reviews and evaluates its procedures in order to optimize and ensure compliance at all levels of sample data collection and handling.

Criteria

JORC Code explanation

Commentary

Mineral tenement and land tenure status

• Type, reference name/number, location and ownership including agreements or material issues with third parties such as joint ventures, partnerships, overriding royalties, native title interests, historical sites, wilderness or national park and environmental settings.
• The security of the tenure held at the time of reporting along with any known impediments to obtaining a licence to operate in the area.

• The Shaakichiuwaanaan Property (formerly called "Corvette") is comprised of 463 CDC claims located in the James Bay Region of Quebec, with Lithium Innova Inc. (wholly owned subsidiary of Patriot Battery Metals Inc.) being the registered title holder for all of the claims. The northern border of the Property's primary claim block is located within approximately 6 km to the south of the Trans-Taiga Road and powerline infrastructure corridor. The CV5 Spodumene Pegmatite is accessible year-round by all-season road is situated approximately 13.5 km south of the regional and all–weather Trans-Taiga Road and powerline infrastructure. The CV13 and CV9 spodumene pegmatites are located approximately 3 km west-southwest and 14 km west of CV5, respectively.
• The Company holds 100% interest in the Property subject to various royalty obligations depending on original acquisition agreements. DG Resources Management holds a 2% NSR (no buyback) on 76 claims, D.B.A. Canadian Mining House holds a 2% NSR on 50 claims (half buyback for $2M), Osisko Gold Royalties holds a sliding scale NSR of 1.5-3.5% on precious metals, and 2% on all other products, over 111 claims, and Azimut Exploration holds 2% on NSR on 39 claims.
• The Property does not overlap any atypically sensitive environmental areas or parks, or historical sites to the knowledge of the Company. There are no known hinderances to operating at the Property, apart from the goose harvesting season (typically mid-April to mid-May) where the communities request helicopter flying not be completed, and potentially wildfires depending on the season, scale, and location.
• Claim expiry dates range from September 2025 to July 2027.

Exploration done by other parties

• Acknowledgment and appraisal of exploration by other parties.

• No core assay results from other parties are disclosed herein. 
• The most recent independent Property review was a technical report titled "NI 43–101 Technical Report, Preliminary Economic Assessment for the Shaakichiuwaanaan Project, James Bay Region, Quebec, Canada" by Todd McCracken, P.Geo., Hugo Latulippe, P.Eng., Shane Ghouralal, P.Eng., MBA, and Luciano Piciacchia, P.Eng., Ph.D., of BBA Engineering Ltd., Ryan Cunningham, M.Eng., P.Eng., of Primero Group Americas Inc., and Nathalie Fortin, P.Eng., M.Env., of WSP Canada Inc., Effective Date of August 21, 2024, and Issue Date of September 12, 2024.

Geology

• Deposit type, geological setting and style of mineralization.

• The Property overlies a large portion of the Lac Guyer Greenstone Belt, considered part of the larger La Grande River Greenstone Belt and is dominated by volcanic rocks metamorphosed to amphibolite facies. The claim block is dominantly host to rocks of the Guyer Group (amphibolite, iron formation, intermediate to mafic volcanics, peridotite, pyroxenite, komatiite, as well as felsic volcanics). The amphibolite rocks that trend east-west (generally steeply south dipping) through this region are bordered to the north by the Magin Formation (conglomerate and wacke) and to the south by an assemblage of tonalite, granodiorite, and diorite, in addition to metasediments of the Marbot Group (conglomerate, wacke). Several regional-scale Proterozoic gabbroic dykes also cut through portions of the Property (Lac Spirt Dykes, Senneterre Dykes).
• The geological setting is prospective for gold, silver, base metals, platinum group elements, and lithium over several different deposit styles including orogenic gold (Au), volcanogenic massive sulfide (Cu, Au, Ag), komatiite-ultramafic (Au, Ag, PGE, Ni, Cu, Co), and pegmatite (Li, Ta).
• Exploration of the Property has outlined three primary mineral exploration trends crossing dominantly east-west over large portions of the Property – Golden Trend (gold), Maven Trend (copper, gold, silver), and CV Trend (lithium, tantalum). The CV5 and CV13 spodumene pegmatites are situated within the CV Trend. Lithium mineralization at the Property, including at CV5, CV13, and CV9, is observed to occur within quartz-feldspar pegmatite, which may be exposed at surface as high relief 'whale-back' landforms. The pegmatite is often very coarse-grained and off-white in appearance, with darker sections commonly composed of mica and smoky quartz, and occasional tourmaline.
• The lithium pegmatites at Shaakichiuwaanaan are categorized as LCT Pegmatites. Core assays and ongoing mineralogical studies, coupled with field mineral identification and assays confirm spodumene as the dominant lithium-bearing mineral on the Property, with no significant petalite, lepidolite, lithium-phosphate minerals, or apatite present. The spodumene crystal size of the pegmatites is typically decimetre scale, and therefore, very large. The pegmatites also carry significant tantalum values with tantalite indicated to be the mineral phase.

Drill hole Information

• A summary of all information material to the understanding of the exploration results including a tabulation of the following information for all Material drill holes:
  • easting and northing of the drill hole collar
  • elevation or RL (Reduced Level – elevation above sea level in metres) of the drill hole collar
  • dip and azimuth of the hole
  • down hole length and interception depth
  • hole length.
• If the exclusion of this information is justified on the basis that the information is not Material and this exclusion does not detract from the understanding of the report, the Competent Person should clearly explain why this is the case.

• Drill hole attribute information is included in a table herein.
• Pegmatite intersections of <2 m are not typically presented as they are considered insignificant. 

Data aggregation methods

• In reporting Exploration Results, weighting averaging techniques, maximum and/or minimum grade truncations (eg cutting of high grades) and cut-off grades are usually Material and should be stated.
• Where aggregate intercepts incorporate short lengths of high grade results and longer lengths of low grade results, the procedure used for such aggregation should be stated and some typical examples of such aggregations should be shown in detail.
• The assumptions used for any reporting of metal equivalent values should be clearly stated.

• Length weighted averages were used to calculate grade over width.
• No specific grade cap or cut-off was used during grade width calculations. The lithium and tantalum length weighted average grade of the entire pegmatite interval is calculated for all pegmatite intervals over 2 m core length, as well as higher grade zones at the discretion of the geologist. Pegmatites have inconsistent mineralization by nature, resulting in some intervals having a small number of poorly mineralized samples included in the calculation. Non-pegmatite internal dilution is limited to typically <3 m where relevant and intervals indicated when assays are reported.
• No metal equivalents have been reported.

Relationship between mineralization widths and intercept lengths

• These relationships are particularly important in the reporting of Exploration Results.
• If the geometry of the mineralization with respect to the drill hole angle is known, its nature should be reported.
• If it is not known and only the down hole lengths are reported, there should be a clear statement to this effect (eg 'down hole length, true width not known').

• At CV5, geological modelling is ongoing on a hole-by-hole basis and as assays are received. However, current interpretation supports a principal, large pegmatite body of near vertical to steeply dipping orientation, flanked by several subordinate pegmatite lenses (collectively, the 'CV5 Spodumene Pegmatite')
• At CV13, geological modelling is ongoing on a hole-by-hole basis and as assays are received. However, current interpretation supports a series of sub-parallel trending sills with a flat-lying to shallow northerly dip (collectively, the 'CV13 Spodumene Pegmatite')
• At CV9, geological modelling is ongoing on a hole-by-hole basis and as assays are received. However, current interpretation indicates CV9 is comprised of a single principal dyke, which outcrops at surface, has a steep northerly dip, and is moderately plunging to the east-southeast. A strike length of 450 m has been delineated through drilling and outcrop.
• All reported widths are core length. True widths are not calculated for each hole due to the relatively wide drill spacing at this stage of delineation and the typical irregular nature of pegmatite, as well as the varied drill hole orientations. As such, true widths may vary widely from hole to hole.

Diagrams

• Appropriate maps and sections (with scales) and tabulations of intercepts should be included for any significant discovery being reported These should include, but not be limited to a plan view of drill hole collar locations and appropriate sectional views.

• Please refer to the figures included herein as well as those posted on the Company's website.

Balanced reporting

• Where comprehensive reporting of all Exploration Results is not practicable, representative reporting of both low and high grades and/or widths should be practiced to avoid misleading reporting of Exploration Results.

• Please refer to the table(s) included herein as well as those posted on the Company's website. 
• Results for pegmatite intervals <2 m are not reported.

Other substantive exploration data

• Other exploration data, if meaningful and material, should be reported including (but not limited to): geological observations; geophysical survey results; geochemical survey results; bulk samples – size and method of treatment; metallurgical test results; bulk density, groundwater, geotechnical and rock characteristics; potential deleterious or contaminating substances.

• The Company is currently completing site environmental work over the CV5 and CV13 pegmatite area. 
• The Company has completed a bathymetric survey over the shallow glacial lake which overlies a portion of the CV5 Spodumene Pegmatite. The lake depth ranges from <2 m to approximately 18 m, although the majority of the CV5 Spodumene Pegmatite, as delineated to date, is overlain by typically <2 to 10 m of water.
• The Company has completed significant metallurgical testing comprised of HLS and magnetic testing, which has produced 6+% Li₂O spodumene concentrates at >70% recovery on both CV5 and CV13 pegmatite material, indicating DMS as a viable primary process approach, and that both CV5 and CV13 could potentially feed the same process plant. A DMS test on CV5 Spodumene Pegmatite material returned a spodumene concentrate grading 5.8% Li₂O at 79% recovery, strongly indicating potential for a DMS only operation to be applicable. Additionally, a more expansive DMS pilot program has been completed, including with non-pegmatite dilution, and has produced results in line with prior testwork.
• Various mandates required for advancing the Project towards Feasibility have been initiated, including but not limited to, environmental baseline, metallurgy, geomechanics, hydrogeology, hydrology, stakeholder engagement, geochemical characterization, as well as mining, transportation, and logistical studies.

Further work

• The nature and scale of planned further work (eg tests for lateral extensions or depth extensions or large-scale step-out drilling).
• Diagrams clearly highlighting the areas of possible extensions, including the main geological interpretations and future drilling areas, provided this information is not commercially sensitive.

• The Company intends to continue drilling the pegmatites of the Shaakichiuwaanaan Property, focused on the CV5 Pegmatite and adjacent subordinate lenses, as well as the CV13 Pegmatite and related prospective corridors.