DEEP YELLOW LIMITED - Capital/Financing Update 2024

NEWS RELEASE

26 February 2024

STRONG RESOURCE UPGRADE DRIVES MULGA ROCK VALUE

HIGHLIGHTS

Total contained uranium in the Mulga Rock East Project increases 26% to 71.2 Mlb U3O8 from 56.7 Mlb U3O8 at a 100 ppm U3O8 cut-off grade, with a substantial uplift also achieved in critical mineral value (including Rare Earth Oxide)
86% of Mulga Rock East uranium resource now in Measured and Indicated classification using a 100 ppm U3O8 cut-off grade
Critical minerals’ inventory ( Cu, Ni, Co, Zn component) increased by between 200% and 400%, depending on element
Updated total Mineral Resources Estimate at Mulga Rock East deposits now: - Ambassador: 73.9 Mt at 605 ppm U3O8 Equivalent
- Princess: 7.3 Mt at 425 ppm U3O8 Equivalent
Mineral Resource Estimate update justifies more expansive Definitive Feasibility Study revision to commence in Q2/2024
Mulga Rock West deposits remain to be assessed for critical minerals

Uranium developer Deep Yellow Limited (ASX: DYL) ( Deep Yellow or Company ) is pleased to announce an updated Mineral Resource Estimate ( MRE ) for the Ambassador and Princess deposits, which form part of its 100%-owned Mulga Rock Project ( MRP or Project ) located in Western Australia’s eastern goldfields. The MRP comprises the Mulga Rock East deposits (Ambassador and Princess) and Mulga Rock West deposits (Shogun and Emperor) (refer Figure 1).

Deep Yellow Managing Director and CEO John Borshoff said: “When we acquired Mulga Rock through the Vimy Resources merger in August 2022 we identified significant opportunity to uplift the value of the Project by considering extracting the critical minerals (Cu, Ni, Co, Zn, Nd, Tb, Dy, Pr) in addition to the uranium associated with the Ambassador and Princess deposits.”

“In order to re-rate and grow this project we needed to undertake a considerable amount of preparatory drilling for essential metallurgical testwork to establish the leaching characteristics of the critical minerals and prepare an updated MRE focusing on both the uranium and nonuranium (critical minerals) components associated with the deposits. The results to date confirm our positive expectation for this exciting project with results illustrating the potential value uplift that could be captured by the integrated development approach. The updated MRE has delivered an impressive 26% increase in the uranium resource and more than doubled the critical minerals’ inventory. This fully justifies proceeding with the DFS revision, which will kick off in Q2 2024, to determine the overall viability of the polymetallic resource that has been delineated with uranium still remaining the key value driver of the Project.”

“Importantly, through our successful work at MRP and the advanced stage of our flagship Tumas Project in Namibia, where we will make a Final Investment Decision in Q3 this year, Deep Yellow is well-positioned to become a geographically diversified, multi-mine uranium producer in the coming years, with assets planned for production by 2026 at Tumas and 2028 at MRP.”

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Level 1, 502 Hay Street, Subiaco, WA 6008 Australia PO Box 1770, Subiaco, WA 6904 Australia ABN: 97 006 391 948 +61 8 9286 6999 [email protected]

www.deepyellow.com.au DYL: ASX & NSX (Namibia) DYLLF: OTCQX

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MULGA ROCK EAST RESOURCES

As shown in the tables immediately below. The total Measured, Indicated, and Inferred U3O8-only Mineral Resources at a 100 ppm U3O8 cut-off in the Mulga Rock East deposits are now 81.2 Mt at 400 ppm U3O8, for a total of 71.2 Mlb U3O8.

Uranium Resources

Class	PREVIOUS MRE	PREVIOUS MRE	PREVIOUS MRE	UPDATED MRE	UPDATED MRE	UPDATED MRE
	Tonnes (Mt)	U3O8		Tonnes (Mt)	U3O8
		(ppm)	(Mlb)		(ppm)	(Mlb)
Measured	5.2	1,100	12.6	12.9	514	14.6
Indicated	16.8	799	29.6	57.2	370	46.5
Inferred	16.2	406	14.5	11.1	413	10.1
TOTAL	38.2	673	56.7	81.2	400	71.2

Critical Minerals Resources

Deposit1	Class	Tonnes (Mt)	Cu (ppm)	Cu (kt)	Ni (ppm)	Ni (kt)	Co (ppm)	Co (kt)	REO1 (ppm)	REO (kt)	Zn (ppm)	Zn (kt)
Ambassador	Measured	12.9	675	8.7	800	5.2	440	5.7	940	12.2	2,720	35,2
Ambassador	Indicated	52.2	495	25.8	785	41.0	465	24.4	605	31.7	1,400	73,1
Ambassador	Inferred	8.7	190	1.7	125	1.1	65	0.6	280	2.4	275	1,5
Princess	Indicated	5.0	810	4.0	500	2.5	305	1.5	175	0.9	1,270	4.6
Princess	Inferred	2.4	510	1.2	395	0.9	230	0.6	185	0.4	910	1.0
TOTAL		81.2	510	41.4	690	55.9	405	32.7	585	47.6	1,465	119.1

The reduction in the overall uranium grade determined for the Mulga Rock East deposits in the latest MRE, decreasing 40% from 673 ppm U308 to 400 ppm, was expected. This reduction is primarily due to the inclusion of lower grade uranium mineralisation outside the primary uranium wireframes but within the critical minerals’ mineralisation envelope. This overall transfer of previously lower grade Inferred category material into Indicated contributed to this decrease in grade. The overall result is an increase in uranium metal – approximately 26% (from 56.7 Mlb to 71.2 Mlb), and the lower uranium grade is fully compensated for by inclusion of the critical minerals into the updated MRE. This positive increase in both total contained uranium and critical minerals can be observed through the U308 equivalency determination.

The individual Mineral Resources for the critical metals (Cu, Ni, Co, Zn and Rare Earth Oxides ( REO )) are listed in Appendix 1 (refer Table 2, pg.16) and show increases of between 200% to 400% (for base metals) compared to the previously reported inventory. Note the REO component has not been previously reported.

Including the critical minerals’ content reported as U3O8 Equivalent ( U308Eq ) values at a 100 ppm U3O8Eq cut-off grade, the Mulga Rock East Deposits now comprise a Measured and Indicated Mineral Resource of 70.1 Mt at 605 ppm U3O8Eq for 93.5 Mlb U3O8Eq and an Inferred Mineral Resource of 11.1 Mt at 481 ppm U3O8Eq for 11.8 Mlb U3O8Eq, totalling 105.3 Mlb U3O8Eq at 590 ppm U3O8Eq (refer section Cut-off Grade (Uranium and Critical Minerals) and Modifying Factors and Appendix 1, Table 2 (pg.16) for individual element tonnes, grade and metal content).

The MRE was undertaken using various cut-off grades using a minimum thickness of 1 m and conforms to the 2012 JORC Code of Mineral Resources Reporting (refer Appendix 1, Table 2 pg.16).

The spatial footprint of the polymetallic mineralisation at these deposits is virtually unchanged from the uranium-only footprint, allowing optimisation of the operation in line with current approvals, which allow for the recovery of critical minerals at the Project.

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Figure 1: Ambassador and Princess Deposits ( Mulga Rock East Deposits ) and Emperor and Shogun Deposits ( Mulga Rock West Deposits ).

TOTAL MULGA ROCK PROJECT URANIUM RESOURCE STATUS

Total Measured, Indicated, and Inferred U3O8-only Mineral Resources at a 100 ppm U3O8 cut-off in the total MRP are now 115.1 Mt at 420 ppm U3O8, for a total of 104.8 Mlb U3O8 (refer Appendix 1, Table 1 pg.16).

CRITICAL MINERALS’ RESOURCE STATUS

The MRE has, for the first time, fully evaluated the potential for critical minerals within the Mulga Rock East deposits. Previously in 2015, only those elements present in the primary uranium domains were reported while the critical minerals’ dataset and grade distribution extending beyond the purely uranium domains were ignored. Importantly, these other critical mineral domains also contain lower grade uranium which otherwise would not have the potential to be economically recovered. Using a 100 ppm U3O8Eq cut-off grade the two Mulga Rock East deposits contain 41.4 Kt Cu at 510 ppm, 119.1 Kt Zn at 1,465 ppm, 55.9 Kt Ni at 690 ppm, 32.7 Kt Co at 405 ppm and 47.6 Kt REO at 585 ppm.

When all material is reported using an U3O8Eq value (refer section Cut-off Grade (Uranium and Critical Minerals) and Modifying Factors for definition), the Mulga Rock East project stands at 81.2 Mt at 590 ppm for 105.3 Mlb U3O8Eq indicating the substantial value added to the Project with the inclusion of these critical minerals.

DISCUSSION

A revised MRP DFS, planned to commence in Q2 CY2024, will utilise both the MRE update and the significant breakthrough with the metallurgical testwork that has occurred in the recovery of critical minerals (copper, cobalt, nickel, zinc and REO collectively, refer to ASX announcement dated 2 November 2023).

The revised DFS will integrate re-scheduling of the mining, using a less selective approach, and potentially capturing much greater value presented by the coincident uranium and critical minerals of the Mulga Rock East deposits while operating within the permitting footprint.

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Mineralisation Distribution

The mineralisation at Mulga Rock East occurs as a set of mineralised tributaries to the broader Mulga Rock palaeochannel (refer Figure 2) contained within Mining Lease 39/1104. Those tributaries have been divided into Ambassador South, Ambassador West, Ambassador East, Princess and Ambassador North sub-deposits based on well-defined geological boundaries.

Figures 2 to 8 show the Ambassador and Princess deposits drill hole locations with the collars coloured according to grade thickness (GT- ppm x metre thickness) for uranium, uranium equivalent, nickel, copper, cobalt, zinc and REO. It outlines the extent and nature of the mineralisation over the 9 km length of palaeochannel tested, the focus of this current MRE work.

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Figure 2: U3O8 Accumulation Map (Ambassador and Princess Deposits) Showing The Surface Projection of Cross-Sections in Figures 9 to 11.

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Figure 3: U3O8Eq Accumulation Map (Ambassador and Princess Deposits).

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Figure 4: Nickel Accumulation Map (Ambassador and Princess Deposits).

The most significant accumulations of nickel and cobalt in the Ambassador and Princess deposits coincide with the Ambassador East and the central portion of Ambassador West (refer Figures 4 and 5).

Those two elements are closely correlated in the assay data, with a high Co/Ni ratio typically greater than 0.45, reflecting the result of supergene enrichment processes.

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Figure 5: Cobalt Accumulation Map (Ambassador and Princess Deposits).

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Copper accumulations show more pronounced zonation, with the central portion of the Ambassador East and western portion of the Princess deposits showing the most significant endowment (refer Figure 6).

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Figure 6: Copper Accumulation Map (Ambassador and Princess Deposits).

This contrasts with the distribution of zinc (refer Figure 7), which shows a primary accumulation within the central part of the Ambassador East deposit.

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Figure 7: Zinc Accumulation Map (Ambassador and Princess Deposits).

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The distribution of REO (refer Figure 8) suggests a strong spatial association with interpreted fault zones that bound the Ambassador East sedimentary trough and the main fault corridor dividing Ambassador West from Ambassador East.

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Figure 8: Rare Earth Oxides (REO) Accumulation Map (Ambassador and Princess Deposits).

Three cross-sections through the Mineral Resource of the Mulga Rock East mineralisation are shown in Figures 9 to 11, reported in U3O8Eq.

This data illustrates the effect of critical minerals on the vertical extent of mineralisation at the Ambassador and Princess deposits, and potential effect on the strip ratio of the future operation.

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Figure 9: Cross-Section CS2 (Ambassador West and East, for Grade X Thickness > 100 ppm U3O8Eq over 1 m).

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Figure 10: Cross-Section CS5 (Ambassador West, for Grade X Thickness > 100 ppm U3O8Eq over 1 m).

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Figure 11: Cross-Section CS8 (Princess, for Grade X Thickness > 100 ppm U3O8Eq over 1 m).

AMBASSADOR AND PRINCESS MINERAL RESOURCE ESTIMATE SUMMARY

The following summarises the material information used to estimate the Mineral Resources as required by Listing Rule 5.8.1 and JORC 2012 Reporting Guidelines.

The MRE update covers the Ambassador and Princess deposits between coordinates 573,875E and 583,900E, as shown in Figures 2 to 7.

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Cut-off Grade (Uranium and Critical Minerals) and Modifying Factors

Based on previous mining studies updated for cost escalation since 2017 and long-term price assumptions listed in Table 1 (pg.9), the final MRE was reported at a cut-off grade of 100 ppm U3O8.

The Mineral Resources derived from these cut-off grades indicate limited sensitivity to the cut-off grade.

Analysis of cut-off grade on a uranium and uranium equivalent basis shows very little difference (<5 ppm, when accounting for additional processing costs for the critical minerals) and, on that basis, can be used interchangeably.

U3O8Eq grades are calculated as follows:

U3O8Eq = U3O8 + 0.093xCo + 0.028xCu + 0.074xNi + 0.118xREO + 0.009xZn

Those factors were calculated using the assumptions presented in Table 1 (pg.9) and, based on testwork completed to date, the Company believes that all the critical minerals (Co, Cu, Ni, Zn, REO) can be recovered and a saleable product can be produced for each relevant element.

Long-term price assumptions were derived using TradeTech® proprietary FAM2 supply/demand scenario (2023 Q3) for uranium oxide and cost curves-based (~ 75% percentile) or consensus analyses for cobalt, copper, nickel and zinc.

Analysis of price variations for critical minerals indicates minimal change in the resulting U3O8Eq cut-off grade.

Long-term ( LT ) prices for REO were assigned using independent long-term prices derived from a composite of industry specialists (based on individually modelled 20-year prices for individual REOs).

Only Magnetic Rare Earth Oxides ( MREO , or the sum of Dy2O3, Nd2O3, Pr2O3 and Tb2O3), which account for about 35% of the total REO by weight and approximately 90% by value at the MRP, were assigned a value for equivalent grade reporting purposes.

Table 1: Mulga Rock East – Uranium Equivalent Grade Reporting Assumptions.

Element	U3O8	Co	Cu	Ni	REO	Zn
Price Assumption(US$/t)	187,423	35,000/t	9,000	22,000	65,2011	2,500
Recovery2	93%	57%	68%	72%	55%	74%
Payability	98%	85%	85%	85%	60%	85%

1 LT Price assumption of US$65,201/t if expressed as the sum of MREO grades.

2 Combined physical beneficiation and leach extraction.

When compared to the previous MRE for the Mulga Rock East deposits (refer Table 2, pg.10), the key differences are associated with a change in estimation method from Ordinary Kriging ( OK ) to Multiple Indicator Kriging ( MIK ) for uranium, the conversion of some of the previous Inferred Mineral Resources resulting from the completion of the recent infill drilling, and a portion of the 2017 Ambassador South Inferred Mineral Resource not converting to an Indicated status.

Before additional drilling at the Ambassador and Princess deposits ( Mulga Rock East ) in 2022 and 2023, the Measured and Indicated Mineral Resources to Total Mineral Resources ratio stood at 74%. The ratio is now 86%.

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Table 2: Mulga Rock East – Comparison Between Previous and Updated MRE, 100 ppm U3O8 and 100 ppm U3O8Eq Cut-Off Grades.

Class	PREVIOUS MRE	PREVIOUS MRE	PREVIOUS MRE		UPDATED	UPDATED	MRE	MRE
	Tonnes (Mt)	U3O8		Tonnes (Mt)	U3O8		U308Eq
		(ppm)	(Mlb)		(ppm)	(Mlb)	(ppm)	(Mlb Eq)
Measured	5.2	1,100	12.6	12.9	514	14.6	785	22.4
Indicated	16.8	799	29.6	57.2	370	46.5	565	71.1
Inferred	16.2	406	14.5	11.1	413	10.1	481	11.8
Total	38.2	673	56.7	81.2	400	71.2	590	105.3

* Rounding has been applied and numbers might not add up.

Table 1 in Appendix 1 (pg.16) outlines the combined Mineral Resources of the entire MRP, which will underpin the DFS revision.

Deposit Parameters

The Ambassador and Princess deposits are of the palaeochannel-hosted type located within a regionally extensive palaeodrainage system.

The Ambassador, Princess and Shogun deposits are supergene deposits associated with multiple phases of weathering, the most recent of which have occurred within the last 300,000 years. The mineralogy of the MRP is diverse, with over 50 minerals being recognised at the Shogun Deposit in addition to the common rock-forming minerals. The bulk of the uranium occurs as diffuse concentrations, too fine to be resolved by scanning electron microscopy ( SEM ) and disseminated throughout the organic matter-rich sediments.

The major zone of uranium accumulation within each deposit occurs as a sub-horizontal planar body strongly correlated with the groundwater surface and fine textured, carbonaceous sediments such as lignites and lignitic clays. It is theorised that uranium (and other base metals within the deposit) were transported laterally from source materials in oxidised form by acidic, meteoric flow. The metals were then concentrated and eventually fixed (reduced) in the anoxic, capillary fringe around the surface of the water table.

Uranium reduction and fixation (U[6+] to U[4+] ) is considered to be largely biogenic (enzymatically catalysed reduction by U-bacteria). The anoxic (reduced) capillary fringe is much thicker in fine-textured sediments (such as lignites) than in coarser-textured sediments such as carbonaceous sands. As such, uranium accumulation in the MRP is dominantly associated with organic matter-rich materials near the water table surface. Uranium accumulation does occur at the water table surface in medium to coarse sands but is generally too thin to be of commercial value. More redox-sensitive metals (such as Cu, Ni and Zn) tend to reduce and fix along redox interfaces below the water table surface. Mineralisation, therefore, is controlled by the lithological and geochemical properties of the sediments rather than by stratigraphy. Suitable lithological and geochemical environments for significant metal accumulation occur in both remnant carbonaceous Cretaceous sediments and Eocene palaeochannel sediments.

Eocene palaeochannel sediments primarily host the mineralisation in the deposits. Uranium mineralisation commences at depths ranging typically between 30 m and 50 m at Ambassador, reflecting the combination of a slight dip to the mineralised surface and the topography of the area. Uranium mineralisation at Princess commences at depths ranging from 36-60 m, with depths increasing to the east. Uranium mineralisation at Shogun commences at depths ranging from 23-24 m.

Deep Yellow is responsible for the drill hole database and geology used in the Mineral Resource, with data compiled in a DataShed database system.

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Drilling Information

The Ambassador drilling dataset used for the 2024 Mineral Resource, shown in Figures 2 to 6, contains 2,453 drill holes (totalling 144.3 km of drilling), of which 2,407 holes contained either radiometric or assay data (refer Appendix 2, Table 2: Drill Hole Details (pg.26).

The holes comprise a mixture of data including:

recent radiometric probe data primarily from aircore ( AC ) and reverse circulation ( RC holes;
historical and recent chemical assay data primarily from diamond core holes; and
some historical radiometric data from Power Reactor and Nuclear Fuel Development Corporation of Japan ( PNC ) drillholes.

The drillholes within the Ambassador deposit reported here comprise:

1,938 AC holes (115,223 m total).
357 diamond holes (19,019 m total).
143 RC holes (9,694 m total).
5 sonic holes (265 m total).
10 geotech holes (51 m total).

Drillholes omitted for resource estimation tended to lack critical radiometric and/or assay data.

The Princess drilling dataset used for the 2024 Mineral Resource, shown in Figures 2 to 6, contains 275 drill holes (totalling 14.0 km of drilling), of which 247 holes contained either radiometric or assay data.

The drill holes within the Princess deposit reported here comprise:

210 AC holes (11,985 m total);
21 diamond holes (1,108 m total); and
16 RC holes (941 m total).

The mineralised zones were defined by interpretation of stratigraphy, geology, and anomalous grades. Using geology and stratigraphic positions, the uranium mineralised zones were defined using a greater than 100 ppm eU3O8 cut-off grade (prior to disequilibrium correction) and/or chemical U3O8 > 100 ppm cut-off grade (for diamond drilling).

A minimum thickness of 1 m was used to define mineralised domains. This protocol defined multiple stacked mineralised zones at Ambassador, with the majority of the metal contained in the upper domain, being the most laterally extensive and highest in grade. Multiple schematic sections of the mineralised domains at Ambassador and Princess are shown in Figures 8 to 10. The metal accumulation maps shown in Figures 2 to 7 primarily reflect the spatial extent of the upper mineralised domain.

Radiometric disequilibrium common in many young uranium deposits was handled as follows:

good quality whole diamond drill core samples were depth-matched with their corresponding downhole wireline data;

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regression equations were derived for the reduced, transitional, and oxidised components of the Ambassador dataset by comparing paired assay data composited to radiometric equivalent grade data. In the majority of cases at Ambassador and Princess, the radiometric eU3O8 grades for similar intervals in the reduced domain are lower than the corresponding chemical assays for U3O8, requiring general positive adjustments to the radiometric data to emulate the accurate chemical assay data. The reverse is true for oxidised and transitional domains; and
factoring was then applied to composites of a similar length to that used in the analysis (nominally 1 m) on the basis of the oxidation-reduction status of the composite, using the following formulae:

Ambassador

Reduced: U3O8 factor = eU3O8 x 1.743 U3O8
Transitional: U3O8 factor = eU3O8 x 0.833 U3O8
Oxidised: U3O8 factor = eU3O8 x 0.833 U3O8

Princess

Reduced: U3O8 factor = eU3O8 x 1.315 U3O8
o Transitional: U3O8 factor = eU3O8 x 0.490 U3O8 o Oxidised: U3O8 factor = eU3O8 x 0.268 U3O8

Chemical assay data primarily formed the basis of the Princess estimate due to a lesser amount of diamond drilling chemical-radiometric assay pairs, with factored radiometric data used when no chemical assay data was available.

Down-hole gamma readings were typically taken at 1-5 cm intervals and converted into equivalent uranium values ( eU3O8 ) before being composited to one-metre intervals.

For details of sample collection and processing relating to pre-2022 drilling programs refer to the detailed report included in the Scheme booklet ASX announcement 16 June 2022 and the Vimy Resources Limited ( Vimy ) announcement to the ASX dated 12 July 2017.

Geochemical assays collected during the 2023 drilling program were collected from one metre AC drilling composites, which were split to 1 kg to 2.5 kg samples by riffle splitters. Crushed samples were pulverised to 90% passing 75 µm prior to laser ablation, with analysis of the fused beads carried out using XRF and ICP-MS methods. For further description of sampling techniques and associated data refer Appendix 2, Table 1 (pg.17).

Estimation Methodology

Data used in the MRE is primarily based on factored down-hole radiometric gamma logging for drill holes other than diamond drilling at Ambassador. Equivalent uranium grades were derived using calibration factors derived from the PIRSA calibration facility in Adelaide prior to drilling.

The block model dimensions at Ambassador cover a region of 10.0 km x 8.3 km.

Estimation for uranium and critical minerals within the uranium mineralisation envelope utilised MIK and OK for critical minerals envelopes, both on 1.0 m composite data.

Parent block dimensions for the Ambassador block model are 50 mE x 50 mN x 1 mRL for both MIK and OK estimates with a smu size of 5 mE x 5 mN x 0.5 mRL for the MIK estimate. Mineralised proportions were applied to the models constructed for both deposits in order to honour the volumes of the supporting mineralised wireframes.

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Variography for the MIK and OK models were completed within the respective modelling packages. For the MIK estimates the data was split in 14 grade bins representing the sample population with variography calculated on each bin range for 4 primary domains – waste, east, west and lower. For the OK estimates variography was calculated for each of the elements of interest within each mineralised domain defined by wireframing.

In general, the variography indicated reasonable grade continuity as defined by the maximum variogram ranges.

The MIK estimate at Ambassador relied on a 5-pass search, with two models constructed:

a first one with a primary search of 50 m x 2 m vertical expanding to a 100 m x 4 vertical; and
a second model with a primary search of 200 m x 8 m vertical and ending at 400 m x 16 m vertical (long-search run).

The two models were then combined by assigning a pass value of 3 to the larger model (roughly equivalent to an Inferred resource classification), and only passes 1 or 2 were copied over from the primary model.

The block dimensions at Princess cover a region of 4 km x 2 km, occurring at the northern extent of the Ambassador block model. Panel size dimensions for the Princess block model are 50 mE x 50 mN x 1mRL with a smu size of 5 mE x 5 mN x 0.5 mRL for the MIK estimate.

Estimation for this Princess update utilises MIK using a 3-pass search on 1.0 m composite data.

The OK models for both deposits used the same model framework, with searches set at 100 m x 2 m vertical, with four sectors and a minimum of samples, followed by a 200 m x 4 m search on two sectors and 8 samples minimum, a third search at 300 m x 6 m on two sectors and 4 samples minimum and a final search at 400 m x 8 m on two sectors and 4 samples minimum. Due to the extent of the deposits and the peripheral drill spacing the Ambassador block model includes an additional pass to populate the wireframe along a 500 m x 10 m vertical search and a minimum of 4 samples.

For the OK estimates of critical minerals and associated uranium appropriate top-cuts were applied to the elements based on the individual sample population distributions.

Classification Criteria

Mineral Resources were classified in accordance with the Australasian Code for the Reporting of Exploration Results, Mineral Resources and Ore Reserves (JORC, 2012). The deposits have been classified as Measured, Indicated and Inferred Mineral Resource based on a combination of quantitative and qualitative criteria which include geological continuity, confidence in volume models, data quality, sample spacing, mineralisation continuity, and estimation parameters (number of informing composites, estimation pass number, kriging quality parameters).

Classification of the final combined Mineral Resources was defined using polygonal assignment with polygons created using drill holes and sample density distribution.

All relevant drill hole details and results were previously reported by Deep Yellow and Vimy in announcements made to the ASX on 14 August 2023, 10 July 2023, 20 January 2023, and 16 June 2022. (Vimy - 26 April 2017, 4 March 2015, 2 April 2012, 10 May 2010, 16 March 2010, 24 February 2010, 29 April 2009, 5 March 2009 and 17 June 2008.)

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All relevant Mineral Resources and mineral inventory were previously reported by Deep Yellow and Vimy in announcements made to the ASX on 28 September 2023 and 16 July 2022. (Vimy - 12 July 2017, 25 May 2017, 8 November 2016, 23 June 2016, 17 September 2015, 20 April 2015, 1 September 2010, 13 January 2009.)

PROSPECTIVITY, AND FUTURE DRILLING

A limited dataset for the spatially extensive Emperor deposit (refer ASX announcement on 16 July 2022, refer also to Vimy ASX announcement on 8 November 2016), suggests localised enrichment in nickel, cobalt, and copper within or immediately below the uranium mineralisation.

Future assessment of critical minerals at Emperor will focus on mine life extension and efficient capture of value presented by uranium and critical minerals in that deposit.

Further resource drilling is planned to continue to the northeast of Ambassador North over a 4.5 km long interpreted extension of the Ambassador tributary (Ambassador Northeast prospect), where historical drill holes were typically not analysed for critical minerals and sparse recent aircore drilling indicates palaeochannel sequences anomalous in critical minerals and low-grade uranium mineralisation.

The compilation of drilling and geophysical data highlights the presence of untested mineralisation to the northeast of the Ambassador North deposit (labelled Ambassador Northeast in Figures 2 to 7).

Those targets will be subject to systematic exploration via drilling in the years to come to quantify their uranium and critical minerals' contents and subsequent conversion to mineral resources if warranted.

CONCLUSION

The Mulga Rock East MRE quantifies both the uranium and critical minerals associated with the Ambassador and Princess deposits with the overall resource base showing significant increase. When combined with the positive results from the metallurgical test work that has been undertaken, this brings the Project to full readiness to commence the next stage of development, which starts with a revision of the 2018 Mulga Rock DFS.

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JOHN BORSHOFF Managing Director/CEO Deep Yellow Limited

This ASX announcement was authorised for release by Mr John Borshoff, Managing Director/CEO, for and on behalf of the Board of Deep Yellow Limited.

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About Deep Yellow Limited

Deep Yellow Limited is successfully progressing a dual-pillar growth strategy to establish a globally diversified, Tier-1 uranium company to produce 10+Mlb p.a.

The Company’s portfolio contains the largest uranium resource base of any ASX-listed company, and its projects provide geographic and development diversity. Deep Yellow has two advanced projects – flagship Tumas, Namibia (FID expected in Q3/CY24) and MRP, Western Australia (advancing through revised DFS), both located in Tier-1 uranium jurisdictions.

Deep Yellow is well-positioned for further growth through development of its highly prospective exploration portfolio – Alligator River, Northern Territory and Omahola, Namibia with ongoing M&A focused on high-quality assets should opportunities arise that best fit the Company’s strategy.

Led by a best-in-class team, who are proven uranium mine builders and operators, the Company is advancing its growth strategy at a time when the need for nuclear energy is becoming the only viable option in the mid-to-long term to provide baseload power supply and achieve zero emission targets. Importantly, Deep Yellow is on track to becoming a reliable and long-term uranium producer, able to provide production optionality, security of supply and geographic diversity.

Competent Person’s Statement

Mineral Resource Estimate

The information in this announcement that relates to the Mulga Rock Mineral Resource Estimate is based on work completed by Mr. D Princep, M.Sc. Geology, who is a Fellow and Chartered Professional of the Australasian Institute of Mining and Metallurgy and has sufficient experience, which is relevant to the style of mineralisation and type of deposit under consideration and to the activity which he is undertaking, to qualify as a Competent Person in terms of the ‘Australasian Code for Reporting of Exploration Results, Mineral Resources and Ore Reserves’ (JORC Code 2012 Edition). Mr. Princep consents to the inclusion in this announcement of the matters based on his information in the form and context in which it appears.

Geophysics Component:

The deconvolution of the relevant Mulga Rock East down-hole gamma data to convert the data to equivalent uranium values (eU3O8) was performed by experienced contractors and audited numerous times.

Where the Company refers to exploration results and other JORC 2012 Mineral Resources previously released in this report, it confirms that it is not aware of any new information or data that materially affects the information included in the original announcements and all material assumptions and technical parameters underpinning the resource estimates in those original announcements continue to apply and have not materially changed.

Forward Looking Statement

Any statements, estimates, forecasts or projections with respect to the future performance of Deep Yellow and/or its subsidiaries contained in this announcement are based on subjective assumptions made by Deep Yellow’s management and about circumstances and events that have not yet taken place. Such statements, estimates, forecasts and projections involve significant elements of subjective judgement and analysis which, whilst reasonably formulated, cannot be guaranteed to occur. Accordingly, no representations are made by Deep Yellow or its affiliates, subsidiaries, directors, officers, agents, advisers or employees as to the accuracy of such information; such statements, estimates, forecasts and projections should not be relied upon as indicative of future value or as a guarantee of value or future results; and there can be no assurance that the projected results will be achieved.

Page 15 of 59

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APPENDIX 1 Table 1: JORC RESOURCES – Mulga Rock Project.

		Cut-off Tonnes U3O8	Cut-off Tonnes U3O8	Cut-off Tonnes U3O8	U3O8	U3O8	Resource Categories(Mlb U3O8)	Resource Categories(Mlb U3O8)	Resource Categories(Mlb U3O8)
Deposit Category		(ppm U3O8) (M) (ppm)			(t)	(Mlb)	Measured	Indicated	Inferred
Western Australia
Mulga Rock Project – JORC 20121
Ambassador	Measured	100	12.9	515	6,638	14.6	14.6	-	-
Ambassador	Indicated	100	52.2	365	19,077	42.1	-	42.1	-
Ambassador	Inferred	100	8.7	480	4,177	9.2	-	-	9.2
Princess	Indicated	100	5.0	405	2,015	4.4	-	4.4	-
Princess	Inferred	100	2.4	170	407	0.9	-	-	0.9
Mulga Rock East Total			81.2	400	32,314	71.2	14.6	46.5	10.1
Shogun	Indicated	1502	2.2	680	1,496	3.2	-	3.2	-
Shogun	Inferred	150	0.9	290	261	0.6	-	-	0.6
Emperor	Inferred	150	30.8	440	13,522	29.8	-	-	29.8
Mulga Rock West Total			33.9	450	15,279	33.6		3.2	30.4
MULGA ROCK PROJECT TOTAL			115.1	420	47,593	104.8	14.6	49.7	40.5

Notes Figures may not add due to rounding. Using combined chemical and radiometric grades.

1 ASX Release dated 12 July 2017.

2 No adjustment made to the Mulga Rock West deposits cut-off grade because those deposits were not re-estimated.

Table 2: Mineral Resources Mulga Rock East Project.

Deposit1	Class	Tonnes (Mt)	U3O8 (ppm)	U3O8 (Mlb)	Cu (ppm)	Cu (kt)	Ni (ppm)	Ni (kt)	Co (ppm)	Co (kt)	REO1 (ppm)	REO (kt)	Zn (ppm)	Zn (kt)
Ambassador	Measured	12.9	515	14.6	675	8.7	800	5.2	440	5.7	940	12.2	2,720	35,2
Ambassador	Indicated	52.2	365	42.1	495	25.8	785	41.0	465	24.4	605	31.7	1,400	73,1
Ambassador	Inferred	8.7	480	9.2	190	1.7	125	1.1	65	0.6	280	2.4	275	1,5
Princess	Indicated	5.0	405	4.4	810	4.0	500	2.5	305	1.5	175	0.9	1,270	4.6
Princess	Inferred	2.4	170	0.9	510	1.2	395	0.9	230	0.6	185	0.4	910	1.0
TOTAL		81.2	400	71.2	510	41.4	690	55.9	405	32.7	585	47.6	1,465	119.1

Notes: Figures may not add due to rounding.

Critical minerals Mineral Resources are reported at a 100 ppm U3O8 cut-off within the uranium envelope and a 100 ppm U3O8Eq cut-off grade within the critical minerals’ envelope.

1 REO were not reported in prior announcements.

Page 16 of 59

APPENDIX 2 Table 1: JORC Code, 2012 Edition.

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Section 1 - Sampling Techniques and Data

(Criteria in this section apply to all succeeding sections.)

Criteria	Commentary	Commentary
*Sampling*	•	The sampling criteria for all drilling was based on their position relative to the main
*techniques*		weathering front.
	•	Sampling started a few metres above the weathering front by placing the sample into a
		plastic bag. The bags were labelled and then left open for a few weeks for the sample to
		dry. After drying, the samples were split using a riffle splitter. Sampling was done at a
		1 m interval.
	•	Downhole logging of natural gamma was used to determine a preliminary equivalent
		U3O8grade, using gamma probes calibrated for uranium in November 2022 at the South
		Australian Government’s Department of Energy and Mining calibration facility in
		Adelaide. The wireline density probe used to measure in-situ bulk density was calibrated
		at the same premises in September 2021. Daily calibrations on the gamma tools were
		carried out using a Cs137jig, with approximately weekly additional calibrations runs
		through a calibration bore at Mulga Rock during the drilling program.
	•	The following wireline logging tools were run in aircore drill holes by contractor Borehole
		Wireline included:
		`o` natural total gamma (in-rod and open-hole configurations);
		`o` dual-spaced focused resistivity/magnetic deviation/gamma;
		`o` dual-spaced induction/gamma;
		`o` single arm caliper; and
		`o` gamma/triple-spaced formation density (using a Cs137source).
	•	Wireline logs were recorded in open hole configuration, following post-drilling
		conditioning of aircore holes with mud, with in-rod gamma logging occasionally carried
		immediately upon completion of drilling to guard against potential caving in the hole
		space.
*Drilling*	•	The 2023 drilling program at Ambassador East, Ambassador West, Ambassador North,
*techniques*		Ambassador South, and Princess relied on aircore drilling.
	•	A range of aircore drill bits was used to deal with varying formation hardness, ranging
		from tungsten carbide blades arranged around an opening in the face of the bit to bits
		fitted with PCD buttons.
	•	Drill hole collars were sited, and coordinates picked up by contractor using a differential
		GPS with an estimated positional accuracy of 5 cm or better.
*Drill sample*	•	Recovery of air-core samples can be uneven due to the variable density, moisture, clay
*recovery*		and organic matter content of the sediments intersected. Sample flow from the cyclone
		was monitored, drilling was suspended, and cuttings residues were scraped out of the
		cyclone where adhesion was evident. Flushing of the cyclone was carried out at the end
		of each 3 m run.
	•	No sample bias has been established historically, nor in the 2023 drilling program.
*Logging*	•	Lithological logging of drill samples was carried out to record primary lithological,
		sedimentological, weathering, colour, and redox features. Stratigraphy is also
		tentatively assigned while drilling and revised following analysis of wireline data. The
		stratigraphic boundaries determined from these graphic logs and associated
		cross- sections were used to model deposit geology and to delimit the ore bodies.
	•	Systematic analysis of the drill core by portable XRF (pXRF) and SWIR-NIR (shortwave
		infrared-near infra-red) analyses is underway on representative 1 m composite samples,
		carried out in-house using a Bruker Titan 800 portable XRF and the company’s Terraspec
		Analytical Spectral Device (ASD model 4).

Page 17 of 59

APPENDIX 2 Table 1: JORC Code, 2012 Edition (continued).

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Criteria	Commentary	Commentary
*Sub-sampling*	•	Selection of sample composites for chemical analysis was based on pre-existing
*techniques*		interpretations of mineralised domains for the drill core and adjusted as necessary based
*and sample*		on downhole wireline radiometric data, as well as systematic portable XRF analyses of
*preparation*		drill cuttings reference samples through plastic bags.
	•	A ca. 1–2.5 kg split was collected after the samples dried to support geochemical
		analyses in a commercial laboratory.
*Quality of*	•	Samples submitted to the laboratory for analysis were subjected to a comprehensive
*assay*		QA/QC program, including submitting in-house and external certified reference materials
*data and*		(CRMs), blanks and laboratory duplicates.
*laboratory*	•	Analysis by portable XRF was carried out by competent operators using blanks, Certified
*tests*		Reference Materials (CRMs), following appropriate warm-up routines.
	•	Portable XRF data is only used for reference and is not used within the MRE.
*Verification of*	•	The depth of down-hole gamma data was checked for discrepancies between the
*sampling and*		recorded total hole depth and the maximum depth of gamma logging, resulting in
*assaying*		occasional re-entry of drill holes and wireline logging through the rod string.
	•	Correlation of core assay data and probe-derived equivalentU3O8grade is used to
		determine a radiometric disequilibrium correction.
*Location of*	•	All holes were re-surveyed by an accredited surveyor or company personnel using a
*data points*		Hemisphere Differential GPS to refine coordinates to be used in future mineral estimates.
	•	The MGA94, zone 51 grid system is used for reporting.
*Data spacing*	•	Drill spacing aimed to achieve a drill spacing of 80 m by 100 m for the infill resource
*and*		drilling. The spacing for the 2023 grade variability drilling program was at 5 m by
*distribution*		10 m.
*Orientation of*	•	Drilling has adequately tested the tabular nature of the mineralisation at Ambassador.
*data in*		However, it is possible that steeply dipping structures may control the distribution of
*relation to*		zones of high-grade and thickness bodies of uranium and base metals mineralisation in
*geological*		sands underlying the upper mineralised lens (hence controlling the upward and lateral
*structure*		migration of hydrogen sulphide). These may require close-spaced angled drilling for a
		complete evaluation of spatial continuity and grade variography.
	•	Aircore and diamond were consistently drilled at least 6 m past the base of uranium
		mineralisation to allow for effective wireline logging of mineralised intervals.
*Sample*	•	A fit-for-purpose chain of custody is maintained during aircore sample dispatch,
*security*		with the cuttings packed into steel drums and strapped onto palettes ahead of dispatch
		to the laboratory.
*Audits or*	•	The Deep Yellow Competent Person has reviewed all information and data used in this
*reviews*		report.
	•	Auditing of equivalent grade derivation was carried out by Deep Yellow competent
		persons.

Page 18 of 59

APPENDIX 2 Table 1: JORC Code, 2012 Edition (continued).

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Section 2 Reporting of Exploration Results (Criteria listed in the preceding section also apply to this section.)

Criteria	Commentary	Commentary
*Mineral*	•	The Ambassador and Princess Deposits are located about 240 km ENE of Kalgoorlie
*tenement*		within Mining Lease M39/1104, held by Narnoo Mining Pty Ltd, a wholly owned
*and land*		subsidiary of Deep Yellow (previously of Vimy Resources Limited (Vimy) prior to its
*tenure status*		merger with Deep Yellow).
	•	Mining Lease M39/1104 is located on Vacant Crown Land. A Native Title claim was
		lodged in December 2020 covering the area of the MRP after the grant of the mining
		lease and environmentalapprovals. The National Native Title Tribunal determined on
		28 November 2023 that Native Title exists in the entire Upurli Upurli Nguratja Native
		Title claim area.
*Exploration*	•	The area of the Ambassador Deposit was subject to uranium exploration by PNC
*done by*		Exploration AustraliaPtyLtd (PNC) during the 1980s, which resulted in the discovery of
*other parties*		the Mulga Rock Deposits. The bulk of PNC’s exploration effort was focused on the
		Ambassador and the eastern side of the Mulga Rock Project between 1982 and 1985.
	•	A trial miningprogramtook place within the Shogun deposit in late 1983 to obtain a bulk
		sample of mineralised lignite.
	•	During 2008 and 2009, Vimy carried out a twin drill hole program followed by an
		extensive infill drilling and sampling program, with statistics as follows:
		`o` 417 aircore drill holes for 27,144 m;
		`o` 27 diamond drill holes for 1,693 m; and
		`o` 5 sonic drill holes for 306 m.
	•	During 2014, Vimy carried a further twin and resource drill-out program (primarily at
		Ambassador East, with several diamond tails drilled at Princess), as follows:
		`o` 144 aircore drill holes for a total of 9,461 m; and
		`o` 42 diamond drill holes for 2,589 m.
	•	In 2015, Vimy carried out an additional infill drill-out program, primarily focused on
		Ambassador West, for the following totals:
		`o` 1035 aircore drill holes for 64,425 m; and
		`o` 144 diamond drill holes for 9,881 m.
	•	In late 2015-2016, Vimy completed two trial pits at Ambassador East and West to
		support geotechnical and metallurgical studies and conducted a reconciliation against
		the resource block model (see announcement to the ASX dated 14 June 2016).
	•	In late 2016, Vimy completed an optimisation drilling program, focused primarily on
		Ambassador East, as follows:
		`o` 215 aircore drill holes for 11,700 m; and
		`o` 84 diamond drill holes for 4,333 m.
	•	In 2016 and 2017, Vimy completed two standalone pilot plants testing the uranium and
		base metals process flowsheets developed for the project.
	•	In early 2018, Vimy released a Definitive Feasibility Study for the Mulga Rock Project
		(announcement to the ASX dated 30 January 2018), updated in 2020 (announcement to
		the ASX dated 26 August 2020), (refer also Deep Yellow ASX announcement 16 June
		2022).
	•	In late 2022, Deep Yellow completed a 63 aircore holes drilling program, for a total of
		4,099 m (see announcement to the ASX dated 23 January 2023).
	•	In August 2023, Deep Yellow completed a 656 aircore holes drill program, split as follows:
		`o` infill drilling: 423 drill holes for 21,853 m; and
	•	close-spaced drilling program: 233 drill holes for 14,794 m, as per ASX announcements
		dated 10 July and 14 August 2023.

Page 19 of 59

APPENDIX 2

Table 1: JORC Code, 2012 Edition (continued).

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Criteria	Commentary	Commentary
*Geology*	•	The Mulga Rock Project is a sediment-hosted uranium resource. The mineralisation that
		comprises the Ambassador and Princess Mineral Resource is hosted by reduced Late
		Eocene sediments preserved within the Narnoo Basin. The Narnoo Basin Sequence
		consists of multiple fining upwards packages, including sandstone, siltstone (typically
		carbonaceous) and lignite, which were deposited in alluvial and lacustrine environments.
		The mineralisation is hosted by reduced sediments of Eocene age preserved within a
		complex set of sedimentary troughs overlying an extensive long- lived palaeodrainage
		referred to as the Mulga Rock palaeochannel, itself likely to represent a dead arm of the
		Lake Raeside regional palaeodrainage.
	•	Overlying the reduced Narnoo Basin sediments is a succession of oxidised sediments that
		are about 25 m to 55 m thick at Ambassador. The pre-Eocene basement in the
		Ambassador area consists of Cretaceous and Carboniferous sedimentary sequences and
		Palaeoproterozoic metasediments to the east of the Gunbarrel fault.
*Drill hole*	•	All 2023 critical minerals' drill hole intercepts relevant to this announcement are
*Information*		provided in Table 2 of Appendix 2 in this announcement.
	•	Nominal vertical depths are reported in Table 1. The shallow drill holes and
		sub-horizontal nature of the host sediments and overprinting weathering profile explain
		the limited deviation from vertical recorded in the wireline data (typically
		1 m or less).
*Data*	•	Equivalent uranium grades have been derived using probe-specific dead time and K
*aggregation*		factors, accounting for the hole diameter, mud density and drill casing steel thickness.
*methods*		Downhole gamma values are composited to 1 m.
	•	There is no known elevated thorium or potassium accumulation within the Mulga Rock
		East part of the project, likely to bias the total gamma readings conversion to
		equivalent uranium grade.
*Relationship*	•	Mineralisation is tabular in habit and horizontal and related to unpressurised
*between*		groundwater flow. The vertical drill hole intersections represent true mineralisation
*mineralisation*		thickness.
*widths and*
*intercept*
*lengths*
*Diagrams*	•	A location map and plan view of drill holes completed during the program are
		provided in the main text, with multiple plans and cross-sectional views of the
	•	Ambassador and Princess deposits included in the body of this announcement.
*Balanced*	•	Balanced reporting has been achieved through a comprehensive reporting of drilling,
*reporting*		sampling and analytical processes followed and complete disclosure of all intercepts.
*Other*	•	The MRE being reported herein builds upon a previously reported MRE (see ASX
*substantive*		announcements dated 28 September 2023 and 16 June 2022).
*exploration*
*data*
*Further work*	•	Modelling of bulk density, moisture and radiometric disequilibrium against whole- rock
		geochemistry via machine learning.
	•	Develop a project-scale geo-metallurgical model applicable to all Mulga Rock
		mineralised material suitable for input into the DFS update process schedule and tailings
		modelling.
	•	Further characterise short-scale (5 m to 10 m) facies, density and grade variability, to
		support the development of a grade control methodology specific to the MRP and
		conditional simulation ofprocessing plant feed variabilityand stockpile management.

Page 20 of 59

APPENDIX 2 Table 1: JORC Code, 2012 Edition (continued).

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Section 3 Estimation and Reporting of Mineral Resources (Criteria listed in the preceding section also apply to this section.)

Criteria	Commentary	Commentary
*Database*	•	A set of SOPs (Standard Operating Procedures) was defined that safeguard data
*integrity*		integrity which covers the following aspects:
		`o` capturing of all exploration data; geology and downhole probing;
		`o` QA/QC of all drilling, geophysical and laboratory data; and
		`o` cata storage (database management), security and back-up.
	•	The resource estimations are based on the available historical exploration and more
		recent drill hole datasets. Deep Yellow manages exploration data in a DataShed
		database system.
	•	Deep Yellow has assumed responsibility for the validity of the drill hole data and geology.
	•	The database was reviewed, and validation checks completed prior to commencing the
		resource estimation study.
	•	The deconvolved radiometric eU3O8grades (before disequilibrium factoring) were
		composited to 1.0 m intervals in conjunction with the assay data to make processing,
		comparison and modelling more efficient. The radiometric data suite allowed for
		cross- checking of assay data, geology, and density.
	•	A final table of ranked assays data was used for the resource estimation with priority
		placed on:
		`o` diamond drilling with chemical data, and
		`o` disequilibrium factored radiometric grades, and
		`o` aircore drilling with chemical data.
	•	Reporting and statistical analyses used industry-standard software packages.
*Site visits*	•	During all drilling programs, regular site visits were conducted by the Company’s
		Competent Person, who signed off on all exploration data, including in 2011, 2012, 2014,
		2015, 2016, 2022 and 2023.
	•	The Competent Person for the Mineral Resource Estimate last visited the site in late 2022.
*Geological*	•	Confidence in the geological interpretation and modelling of the sedimentary channel-
*interpretation*		fill is very high. This type of geology is well-known and readily recognised in aircore drill
		cuttings.
	•	Geology (lithology) was not modelled but used in defining the mineralised zones.
	•	Stratigraphy was modelled and influenced the limits of the interpreted mineralised zones.
	•	Diamond drilling has improved the geological understanding of the deposit. Previously
		the interpretation was complicated by the overprint of oxidation/lithology and
		stratigraphy. A simplified stratigraphic interpretation has been completed and is the
		basis for mineralised domain definition.
	•	The deposit grades are very closely associated with the reduction-oxidation front and
		are highest close to this sub-horizontal boundary.
	•	For the purpose of the resource estimation, the mineralisation boundaries were based on
		a nominal 100 ppmU3O8lower cut-off grade, defining a mineralised zone of at least
		1.0 m thickness and honouring, where possible, the geology/stratigraphy. This value
		represents a natural break in the distribution of equivalent grades distinguishing
		mineralisation from the un-mineralised material.
	•	The factors affecting grade distribution are channel morphology, facies changes,
		underlying basement sequence (metamorphic or sedimentary) and profile, and
		post- depositional faulting, which influenced fluid flow and upward migration of
		hydrogen sulphide thought to account for a significant component of the secondary
		critical minerals sulphides in the mineralisation.

Page 21 of 59

APPENDIX 2

Table 1: JORC Code, 2012 Edition (continued).

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Criteria Commentary	Criteria Commentary	Criteria Commentary	Criteria Commentary	Criteria Commentary
*Dimensions* • •	The block models are not rotated. The block models extents are tabulated below: Mulga Rock Project – Ambassador Deposit Feb 2024 Block Model Construction Parameters Origin (m) Extent (m) Panel/Block SMU Size (m) Easting 573,875 10,025 50/5 Northing 6,676,575 8,325 50/5 Elevation 240 114.2 1.0/0.5 Mulga Rock Project – Princess Deposit Feb 2024 Block Model Construction Parameters Origin (m) Extent (m) Panel/Block SMU Size (m) Easting 578,000 2,600 50/5 Northing 6,683,200 1,800 50/5 Elevation 230 150 1.0/0.5
	Mulga Rock Project – Ambassador Deposit Feb 2024 Block Model Construction Parameters
		Origin (m)	Extent (m)	Panel/Block SMU Size (m)
	Easting	573,875	10,025	50/5
	Northing	6,676,575	8,325	50/5
	Elevation	240	114.2	1.0/0.5

	Mulga Rock Project – Princess Deposit Feb 2024 Block Model Construction Parameters
		Origin (m)	Extent (m)	Panel/Block SMU Size (m)
	Easting	578,000	2,600	50/5
	Northing	6,683,200	1,800	50/5
	Elevation	230	150	1.0/0.5

*Estimation* *and* *modelling* *techniques* • • • • • • • • • • • • • •	Exploratory data analysis, variogram calculation and modelling, and resource estimation were performed using both ©MicroMine and GS3M software. Variography was performed using GS3M for the MIK models and ©MicroMine for the Ordinary Kriging (OK) models. The present estimates are based on grade domains controlling the interpolations into block estimates. Panel sizes used are 50 m East x 50 m West x 1 m elevation. Primary estimation ofU3O8block values used Multi Indicator Kriging (MIK). Mineralisation surfaces were derived around a 100 ppmU3O8minimum value into four domains (East, West and Lower mineralisation and waste). As the primary U3O8estimate was based on MIK, no grade capping was applied. The MIK estimate was based on 14 indicator bin values representing 10% probability increments up to 70%, then 5%incrementsto 95%, then 97%, and 99% to more reasonably model the high-grade component of the dataset. Directional variograms based on 14 indicator bins are used in the current estimates. A maximum search distance of 400 m x 400 m x 16.0 m was used within the Ambassador estimate and 200 m x 200 m x 4.0 m within the Princess estimate. An explicit domain model based on the modelled uranium wireframes was applied during the estimation process. Block validation was done using qualitative drill hole displays over block estimates. The current block estimate throughout correlates well with factored eU3O8GT (Grade- Thickness) data. No correction for water was made other than any that may have been applied during the calculation of downhole equivalent uranium values. A block support correction was applied to the MIK estimate to derive final block proportions and grades. This correction value adjusts the tonnes and grade for each panel based on the likely mining and grade control parameters. The general progression of this process is to increase overall tonnes and reduce overall grades. Final SMU sizes were set at 5 m x 5 m x 0.5 m with a target grade control spacing of 5 m x 5 m x 0.5 m does not require further regularisation and associated dilution. There is potential to recover nickel, cobalt, copper, zinc and rare earth elements (critical minerals collectively) that are a component of the mineralisation), with bulk leach and pilot plant test work indicating potentially high overall extraction rates. For the OK estimates of critical minerals and associated uranium, appropriate top cuts were applied based on an assessment of the population distribution of the individual elements.

Page 22 of 59

APPENDIX 2

Table 1: JORC Code, 2012 Edition (continued).

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Criteria Commentary	Criteria Commentary
*Estimation* *and* *modelling* *techniques* *(continued)* • •	Princess `o` U3O8 7,000 ppm `o` Co 2,600 ppm `o` Cu 9,000 ppm `o` Ni 4,800 ppm `o` Zn 10,000 ppm `o` REO 2,400 ppm Ambassador `o` U3O8 8,500 ppm `o` Co 7,500 ppm `o` Cu 14,000 ppm `o` Ni 13,000 ppm `o` Zn 40,000 ppm `o` REO 6,000 ppm
*Moisture* •	Tonnages and metal are reported on a dry basis, requiring a dry in-situ bulk density. Wet density and moisture are also estimated in the block model for mining studies and metallurgical purposes.
*Cut-off* *parameters* • • • • • • •	Composites less than 0.75 m were excluded from the estimation process. For values based on downhole radiometric logging this only relates to samples at the start or end of drill holes. For sampling based on diamond drilling a small number of samples have been excluded. The final MRE was reported at a range of cut-off grades between 100 ppm and 150 ppm U3O8. The nominal 100 ppmU3O8lower cut-off used to interpret the mineralisation domains was chosen as it represents a natural break in the assay data. A block cut-off grade of 100 ppmU3O8is currently applied for reporting purposes assuming open-pit mining methods, to reflect escalated operating costs from the 2018 DFS and higher revenue. An equivalent uranium cut-off grade of 100 ppm was used for reporting material outside of the primary uranium wireframes estimated using MIK. The equivalency factors were based on the following values: Element U3O8 Co Cu Ni REO Zn Price Assumption(US$/t) 187,423 35,000/t 9,000 22,000 65,201 2,500 Recovery 93% 57% 68% 72% 55% 74% Payability 98% 85% 85% 85% 60% 85% The final equivalency factor equation was: `o` U3O8Eq =U3O8+ 0.093Co + 0.028Cu + 0.074Ni + 0.118REO + 0.009*Zn. The Company believes that all of the critical minerals (Co, Cu, Ni, Zn, REO) can be recovered and a saleable product can be produced for each relevant element.
*Mining* *factors* or *assumptions* • • • • •	The resource has been subject to a Feasibility Study (January 2018), supported by extensive trial mining. Therefore, assumptions on mining methods and parameters are very robust. Relatively shallow open pit mining, incorporating in-pit waste and tailings disposal is assumed for the bulk of the deposit. No mining recovery factor has been applied to theU3O8in the Mineral Resource. Mining is by open pit, and the majority of the mineralisation present within the pit design can be recovered for processing. Block support corrections applied to the MIK portion of the MRE follow the expected mining process. The MRE was assessed for reasonable prospects for eventual economic extraction and the reported estimate reflects the outcome.

Page 23 of 59

APPENDIX 2 Table 1: JORC Code, 2012 Edition (continued).

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Criteria	Commentary	Commentary
*Metallurgical*	•	Factors regarding metallurgy, recovery or processing cost have been applied in deriving
*factors or*		U3O8Eq cut-off grades.
*assumptions*	•	Recent test work at Ambassador has shown potential recoveries greater than 90% for
		both lignite and sand-hosted mineralised material using an atmospheric acid leach
		(tested in a resin-in-pulp configuration).
	•	At Ambassador, spectral, mineralogical, deportment and metallurgical studies show that
		the bulk of the uranium is primarily in a hexavalent ionic state and adsorbed onto organic
		matter, with a negligible fraction contained in refractory minerals.
	•	Metallurgical assumptions to apply to the DFS update will be based on a detailed
		geometallurgical model for the project, which is currently under development.
	•	The process flow sheet for the project has seen extensive bench and bulk leach testwork
		completed by two pilot plants (uranium and critical minerals circuit)
	•	Additional process flow sheet optimisation test work is underway and will underpin the
		feasibility study update.
	•	Also, the current Deep Yellow metallurgical and process development team successfully
		designed, commissioned and operated a first-of-a-kind RIP circuit at the Kaleyekera
		plant in Malawi.
*Environmental*	•	The Project achieved State and Commonwealth environmental permitting in December
*factors or*		2016 and March 2017, respectively, which allows for the recovery of critical minerals.
*assumptions*	•	In June 2017, the WA State Government confirmed that those approvals stand and that
		the Mulga Rock Project can proceed (refer to Vimy ASX announcement “Western
		Australian Government confirms the Mulga Rock Project is allowed to proceed”; 20 June
		2017).
	•	Mining Proposal #92188 and the associated Project Management and Mine Closure Plans
		were approved in September 2021, followed by the approval of a Radiation Management
		Plan in early December 2021.
	•	On 16 December 2021, the DWER Director General confirmed that Vimy had met the
		5-year deadline for substantial commencement of the operation, maintaining the currency
		of its environmental approvals.
*Bulk density*	•	Bulk density has been determined by using both gamma downhole geophysical logging
		of diamond drill holes in the Ambassador deposit and Archimedean data from core
		samples.
	•	The Archimedean density measurements have been used to validate and correct the
		downhole geophysical data where applicable. Downhole gamma data has been
		selectively used where differences have been identified.
	•	Dry bulk density values were determined by converting the wet bulk density using
		moisture values for the corresponding lithology and mineralised domain type.
	•	Bulk densities were estimated directly into the block models and assigned to the
		composite intervals according to the main lithologies discussed above, each assigned
		a specific moisture, wet bulk density and dry bulk density. For details of the methodology
		used, please refer to the Vimy announcement to the ASX dated 12 July 2017.
	•	Those densities were checked using a probability-based lithological model and found to
		be identical.
	•	Density values assigned to the Ambassador and Princess deposits are consistent with
		density of similar lithologies for other deposits in the region.

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APPENDIX 2

Table 1: JORC Code, 2012 Edition (continued).

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Criteria	Commentary	Commentary
*Classification*	•	The Mineral Resource has been classified in accordance with JORC Code 2012 guidelines
		based on the confidence levels of the key criteria considered during the resource
		estimation such as data quality, drilling density, apparent grade and spatial continuity
		of the mineralisation.
	•	The results appropriately reflect the Competent Persons’ view of the deposit.
	•	This MRE reflects a Measured, Indicated and Inferred Mineral Resource.
	•	Semi-variography modelling indicates reasonable long-range grade continuity of
		greater than 500 m.
	•	Maximum search ranges used were set to maximum of 500 m.
	•	The average mineralised thickness for mineralised domains is in the order of 1 m to 8 m
		at Ambassador and 2 m to 7 m at Princess.
	•	The Competent Person is satisfied that the applied methodology is appropriate for
		reporting an Indicated Mineral Resource and that the resulting block estimates are true
		reflections of the underlying drilling data.
*Audits or*	•	No additional reviews were conducted beyond those carried out by the various
*reviews*		Competent Persons over time.
*Discussion of*	•	The applied geostatistical approach applied to arrive at the current Measured, Indicated
*relative*		and Inferred Mineral Resource is considered sound and is appropriate to the style of
*accuracy/*		mineralisation contained within the deposit. The same estimation methodology has been
*confidence*		successfully applied in other palaeochannel-hosted uranium mineralisation.
	•	The presented block model is considered to be a reasonable representation of the
		underlying sample data.
	•	It is this Competent Person’s opinion that the classification of potions of the Indicated
		and Inferred components of the Mineral Resource could be improved to measured status
		by confirming the validity of the currently available bulk density information and further
		infill drilling.

Page 25 of 59

APPENDIX 2 Table 2: Drill Hole Details.

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Drill hole and intercepts details

Coordinate system: Geocentric Datum of Australia (GDA) 1994, Zone 51

Coordinates rounded to the closest 0.1 m.

All holes were drilled vertically; Given the horizontal nature of the deposits, the intercepts thicknesses are reported as true width.

Naming convention:

Prefixes:
Vimy/Deep Yellow:
- NND: Diamond drill hole
- AS: Sonic drill hole
- NNA, NBSP & MET: Aircore drill hole
- NGV: Grade variability aircore drill hole
- NBS: Large diameter diamond drill hole
- NET: Pushtube drill hole
CD: Historical diamond drill hole
RC: Historical reverse circulation drill hole
AC: Historical aircore drill hole
Suffixes:
R: Redrill
B: Redrill

For further details on the drilling techniques and hole details, please refer to the past releases to the ASX referred to in the main body of the announcement.

Intersections report using a cut-off grade of 100 ppm U3O8Eq and a minimum thickness of 1 m.

The basis of U3O8Eq grade reporting is reported in the main body of the announcement.

Blank cells indicate no data.

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