DART MINING NL — Capital/Financing Update 2026

Feb 18, 2026

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ASX Release

19 February 2026

RECORD HIGH GOLD, SILVER, AND ANTIMONY DRILL RESULTS AT COONAMBULA; DEVELOPING A RESOURCE BASE FOR 2026

Dart Mining NL ( ASX:DTM ) ( Dart Mining or the Company ) is pleased to announce assays of drill holes CBADD003 through to CBADD010, received for the Coonambula Antimony (Sb) - Gold (Au) – (Ag) Silver project near Eidsvold in Central Queensland. The results include the highest gold, silver and antimony assays received for the Banshee prospect to date. The project is a Farm-In JV with Great Divide Mining ( ASX:GDM ) (ASX: DTM Mar 2025).

HIGHLIGHTS

• Assays from CBADD003 to CBADD010 have been received, including the highest single assay for gold at the Banshee prospect, exceeding the previously highest intercept reported from CBADD002 (ASX: DTM Dec 2025);

• These results highlight broader gold zones which contain internal rich antimony and silver zones. The three NEW record high drill results for gold, silver, and antimony for the Banshee prospect include:

• 0.2m @ 20.20 g/t Au from 37.7m ( CBADD010 );

• 0.6m @ 234.0 g/t Ag from 57.95m ( CBADD004 ); and

• 0.6m @ 44.6% Sb from 37.9m ( CBADD010 ).

• Broader highlight assays from the seven holes include:

• 9.0m @ 2.67g/t Au + 16.8 g/t Ag + 5.8% Sb from 32.5m ( CBADD010 ) including;

  • 1.2m @ 5.5 g/t Au + 85.1 g/t Ag + 18.8% Sb from 37.7m; and

  • 0.6m @ 1.62 g/t Au + 17.2 g/t Ag + 44.6% Sb from 37.9m; and

  • 0.5m @ 10.75 g/t Au + 3.5 g/t Ag + 4.7% Sb from 39.0m.

• 4.3m @ 3.61 g/t Au + 3.3 g/t Ag + 0.2% Sb from 43.2m (CBADD009) including;

  • 0.9m @ 9.44 g/t Au + 2.3 g/t Ag + 0.5% Sb from 43.2m; and

  • 0.3m @ 4.02 g/t Au + 27.6 g/t Ag + 1.3% Sb from 46.1m.

• 2.2m @ 4.29 g/t Au + 4.0 g/t Ag + 0.2% Sb from 82.9m ( CBADD005 ) including;

  • 0.5m @ 10.05 g/t Au + 1.3 g/t Ag from 84.6m; and

  • 0.4 @ 6.18 g/t Au + 4.3 g/t Ag + 1.0% Sb from 85.1m.

• 1.3m @ 3.80 g/t Au + 131.9 g/t Ag + 10.5% Sb from 8.7m ( CBADD006) ;

Contact: James Chirnside Webpage: www.dartmining.com.au Email: jchirnside@dartmining.com.au LinkedIn: Dart Mining NL Mobile: +61 447 447 613 Twitter: @DartMining

Dart Mining NL ABN: 84 119 904 880 Level 6, 412 Collins Street Melbourne VIC 3000

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• 1.3m @ 2.12 g/t Au + 68.5 g/t Ag + 10.2% Sb from 131.4m ( CBADD003 ) including; • 0.5m @ 2.74 g/t Au + 145.0 g/t Ag + 24.9% Sb from 131.4m.

• 2.1m @ 1.61 g/t Au + 71.5 g/t Ag + 0.5% Sb from 57.5m ( CBADD004 ) including; • 0.6m @ 2.45 g/t Au + 234.0 g/t Ag + 1.8% Sb from 58.0m.

• These drill holes compliment the assays from CBADD001 and CBADD002 by increasing the strike of the Banshee mineralisation to over 320m. Both east and west zones are still open for further expansion. Importantly, the mineralisation is also shown to be open at depth and present at outcrop and within the oxidation zone (<10m from surface).

Dart Mining’s Chairman, James Chirnside, commented: “Dart Mining is very pleased to share these recent drilling results with the market. The drill intercepts have exceeded our expectations with record numbers for gold, silver, and antimony.

We’re starting to see confidence in the continuity of the mineralisation, and we’re also seeing good results, up dip and closer to surface. Our original plan was to target mineralisation deeper in CBADD001 and CBADD002 to ensure we could project more accurately towards surface with CBADD006 highlighting a strong zone of gold, silver, and antimony numbers which do not appear to be affected by weathering.

As we progress drilling, and continue to earn-in to the Coonambula Project, we are looking towards these shallow extensions up dip, with a plan to convert into a maiden Mineral Resource Estimate. The MRE is one of our milestones for the JV, and we look forward to continuing to grow the Banshee story with our ongoing 4,000m drilling programme.

We also note that the historical drilling and sampling, while sparse, appears to be missing zones that the current drill program is targeting. This is a notable development as we look to step out and grow the strike length of the mineralisation.

At this point I’d like to make special mention of our partners at GDM, Dart’s exploration team, and our Drill crews who have worked tirelessly, under challenging conditions, to deliver these excellent results”

Dart Mining has completed 2,594m of diamond core drilling across the Banshee prospect (Figure 2). Drill hole assay results for CBADD003 through CBADD010 represent up to 1,354m of the total 2,594m with the remaining metres pending assay, processing, and logging in due course. Highlight assay results from CBADD003 through CBADD010 are tabulated in Table 1 and a complete Table of collar and assay information is provided as Appendix 1 .

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Figure 1: Location plan showing planned hole locations and preliminary interpretation of mineralisation

Table 1 : Key drill intercepts from Dart Mining ’s diamond drilling at the Coonambula Project (CBADD003 through CBADD010) .

Drill Hole Name	From Depth (m)	Thickness (m)	Au g/t	Ag g/t	Sb %
CBADD003	131.35	1.3	2.12	68.52	10.2
including	131.35	0.5	2.74	145.00	24.9
CBADD003	143.50	1.1	1.61	4.49	0.0
CBADD003	155.00	1.0	6.73	0.88	1.4
CBADD004	52.80	1.0	3.19	0.72	0.0
CBADD004	57.50	2.1	1.61	71.46	0.5
including	57.95	0.6	2.45	234.00	1.8
CBADD004	64.00	1.1	4.03	4.51	3.1
including	64.00	0.6	4.54	6.95	5.6
CBADD004	66.10	1.0	1.80	1.39	0.1
CBADD005	82.90	2.2	4.29	3.99	0.2
including	84.60	0.5	10.05	1.32	0.0
including	85.10	0.4	6.18	4.30	1.0
CBADD005	135.70	0.3	4.67	0.80	0.9
CBADD005a	68.50	8.8	0.79	1.05	0.33
including	69.40	0.9	2.18	2.38	3.1
including	73.70	1.8	1.34	1.75	0.0
CBADD006	8.70	1.3	3.80	131.88	10.5
CBADD007	139.80	2.1	3.22	1.31	3.0
including	141.10	0.4	8.25	3.50	15.5
CBADD008	80.10	1.1	1.77	0.57	0.0
CBADD009	43.20	4.3	3.61	3.31	0.2
including	43.20	0.9	9.44	2.25	0.53
including	46.10	0.3	4.02	27.60	1.3
CBADD010	13.50	0.8	2.62	2.05	0.0
CBADD010	32.50	9.0	2.67	16.8	5.8

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including	36.70	1.2	5.5	85.13	18.84
including	37.90	0.6	1.62	17.2	44.6
Including	39.00	0.5	10.75	3.43	4.7

INTERPRETATION

Now that a significant batch of assays from the initial drilling has been received, Dart Mining is starting to look deeper into the interpretation of the mineralisation intersected. Confidence is growing around predicting higher grade gold zones based on the intensity and type of alteration, as well as the identification of disseminated sulphides, specifically antimony, with stibnite being present in and around fault and breccia zones related to the mineralisation.

A long section highlighting the observations of anomalous mineralisation in the database to date, as well as highlighting the results received from CBADD003 through CBADD010 is shown in Figure 2. Cross section interpretation of the mineralisation intersected in CBADD010 based on assays is shown in Figure 3, while a thicker cross section encompassing CBADD006, CBADD003, and CBADD009 (approximately 50m cross section thickness) is shown in Figure 4.

As Dart Mining continues to explore Banshee, focus on interpretation against analogues for similar orebodies such as Hillgrove (also in the New England Orogen) and Costerfield (Australia’s only antimony producer) will assist in unlocking more of the Banshee story.

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Figure 2: Long section through Banshee Prospect highlighting CBADD003 through CBADD010 assay drill results.

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Figure 3: Cross section through CBADD010

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Figure 4: Cross section through CBADD009 and CBADD004 and CBADD003

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Drill hole CBADD010 has returned the highest gold assay result at the Banshee antimony prospect to date with 0.2m @ 20.20 g/t Au from 37.7m. Previously, the highest drill assay for gold was 0.5m @ 18.30 g/t Au from 184.5m returned from CBADD002 (ASX: DTM Dec 2025). In addition, CBADD010 also returned record antimony results with 44.6% Sb from 37.9m. Consistent with field observations and assays from CBADD001 and CBADD002, the stibnite zones are concentrated within a broader Au zone.

Currently, CBADD010 is the closest drill hole with assays near the historical Banshee antimony mine (~50m away). The intersect highlights mineralisation at 30m below surface. A recently attempted drill hole directly underneath Banshee was completed by Dart Mining and has intersected a void at ~27m below surface (CBADD018). Dart Mining is still working towards understanding the historical development/mining activities related to Banshee and will update the market in due course.

CBADD004 has returned the highest silver results to date with an impressive 0.6m @ 234.0 g/t Ag from 57.95m, which is over 8 ounces of silver per tonne. The observations of not only extensive Sb, but Ag is starting to demonstrate that the Banshee prospect at Coonambula is likely to be an Au-Ag-Sb polymetallic system. With systematic diamond drilling, Dart Mining will continue to expand the mineralisation along strike, towards surface, and at depth.

While the early interpretation work around CBADD001 and CBADD002 showed that the Sb is primarily focused on a high-grade series of stibnite veins within a broader Au zone, this is becoming true with silver as well. Observations of the highly anomalous silver (i.e. > 50g/t Ag) appears to correlate with high Sb. Field observations are limited, but an interpretation is that the silver is part of an argentiferous tetrahedrite freibergite ((Ag, Cu, Fe)₁₂(Sb, As)₄S₁₃) complex. Where Ag is reporting > 50g/t, copper is also highly anomalous with Cu > 100ppm (note background copper is average 20ppm). Figure 5 shows a scatter plot of Ag vs Cu with a strikingly correlated Ag-Cu anomaly. The relationship is less defined with Sb as the mineralisation is predominately stibnite. However, this does highlight that Dart Mining can expect to continue to intersect high grade silver where high grade antimony is intersected, but more importantly, opens up additional primary and pathfinder elements for board scale exploration outside of Banshee for additional similar systems.

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Figure 5: Scatterplot graph highlighting anomalous

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The strike of the Banshee mineralisation presents itself as a slight hill striking roughly NEE/SWW. CNRC05 (historical drill hole) had the shallowest high grade Au drilling across the prospect with 3.0m @ 8.53g/t Au from 18m. CBADD006 was drilled to test what the material in the area looked like and if going shallower (half the distance to surface) would start to alter grades (either leached or concentrated in a supergene). Based on the field observations of CBADD006, which was confirmed by assays, the mineralisation appears to be resilient to weathering especially compared to the host granodiorite. The quartz host of the sulphide mineralisation is intact and relatively unaltered (Figure 6). Figure 6 shows the interval is from 8.7 to 9.8m and contains massive stibnite from 8.7 to 8.8m, and 9.6 to 9.7m. Assays confirmed an intercept of 1.3m @ 3.80 g/t Au + 131.9 g/t Ag + 10.5% Sb from 8.7m .

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Figure 6 : Section of quartz veining hosting stibnite in hole CBADD006.

There has been 1 redrill of CBADD005 due to moderate core loss in a fault gauge/strongly mineralised zone with visible sulphides. CBADD005a (redrill) was drilled to target the same zone and intersected it with good core recovery

COONAMBULA MRE PLANNING

With Dart Mining currently up to 2,594m of the agreed 4,000m to earn 51% of the Coonambula Project, work will focus on systematically building out the drilling programme to pave the way for a maiden Mineral Resource Estimate (MRE). With the consistency of results as well as the continuity of the mineralised corridor to date, Dart Mining is on course to achieve an attractive maiden MRE at the completion of the 4,000m drilling programme. Now that Dart Mining’s Queensland core farm is at full function and capacity, further studies such as density, petrography (as required), and geotechnical logging can become more routine.

Dart Mining is commencing a programme for metallurgical test work to better characterise recovery factors to the support the MRE’s reasonable prospects for eventual economic extraction (RPEEE) as well as establishing a proposed/conceptual flowsheet for processing. It is not yet clear what type of processing options may best suit Banshee, however as more drilling is completed (to determine tonnes and grade potential), as well as detailed metallurgical test work on several composites, Dart Mining will evolve its knowledge to suit the project as required.

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Plans at this stage to determine depletion of the potential maiden MRE around the historical Banshee Mine will likely include continuing to drill shallow holes into the void to establish a basis for the boundary of depletion. Little is known about the specifics of the operation at the Banshee Mine except that it was mining massive stibnite as direct shipping ore (DSO), there have been no records discovered to date on any level plans, extraction methods etc.. As previously mentioned, Dart Mining’s CBADD018 was drilled directly underneath the Banshee pit with the aim to intersect mineralisation at 30m, and a void was intersected at 27m from surface.

PREVIOUS DART RESULTS

Highlight assays from Dart’s first hole, CBADD001, ( ASX: DTM 10 November 2025 ) include:

• 5.0m @ 4.33% Sb + 1.69 g/t Au + 23.65 g/t Ag from 41.5m;

• including 0.65m @ 32.20% Sb + 2.91 g/t Au + 10.50 g/t Ag from 42.0;

• 0.5m @ 2.53 g/t Au from 42.65m and

• 0.7m @ 5.61 g/t Au + 154 g/t Ag from 45.4m.

• 1.6m @ 9.47% Sb + 0.35 g/t Au + 4.09 g/t Ag from 68.2m;

• including 0.5m @ 29.60% Sb + 0.65 g/t Au + 12.60 g/t Ag from 68.7.

Highlight assays from CBADD002 ( ASX: DTM 15 December 2025 ) include:

• Broader gold zones containing antimony mineralised zones

• 1.4m @ 2.00 g/t Au + 0.97% Sb from 134.0m including: ▪ 0.3m @ 7.33 g/t Au + 4.40% Sb from 134.5m.

• 1.0m @ 2.15 g/t Au from 175.5m;

• 6.5m @ 5.1 g/t Au + 0.15% Sb from 180.0m including:

• 1.5m @ 7.32 g/t Au from 182.5m;

• 0.5m @ 18.30 g/t Au from 184.5m; and

• 1.0m @ 6.38 g/t Au + 0.92% Sb from 185.5m.

Dart Mining rock chip sampling revealed high grade antimony, gold and silver ( ASX: DTM 10 October 2025 ). Assays received across 9 samples of float and in situ veins across the historic Banshee antimony mine area include:

• Antimony results up to 65.3% Sb and 55.5% Sb

• Gold grades up to 17.0g/t Au and 15.05g/t Au

• Silver assays up to 97.9g/t Ag and 66.7g/t Ag

Trench sampling conducted immediately south of the Banshee mine confirmed high grade gold, silver and antimony ( ASX: DTM 15 January 2026 ). Samples from regular 1m intervals returned:

• Gold grades up to 10.45g/t Au and 8.92g/t Au

• Silver assays up to 125g/t Ag and 121g/t Ag

• Antimony results up to 5.14% Sb

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Prior to Dart Mining, previous highlights across the project include:

• Highlights from 2014 drilling as per the GDM Prospectus (ASX: GDM Prospectus 2023 ): ▪ 3m @ 9.18% Sb in hole CNRC03 from 158m including 1m @ 25% Sb from 158m ; ▪ 6m @ 5.12% Sb & 1.55 g/t Au in hole CNRC04 from 77m; ▪ 3m @ 1.50% Sb & 8.53 g/t Au in hole CNRC05 from 18m;

• Rock chips of 44.9% Sb, 24.1% Sb, 39.9% Sb, and 39.4% Sb (ASX: GDM Prospectus 2023 ):

• Surface trenching includes 4m@ 3.09 g/t Au and 1.14% Sb and 1m @ 6.15 g/t Au and 3.1% Sb. While trenching, selective rock chips returned 3.65 g/t Au with 23.9% Sb , and 9.93 g/t Au with 7.56% Sb ( ASX: GDM Nov 2024 ).

NEXT STEPS

Dart Mining’s immediate field activities are focused on progressing the farm-in exploration at the Coonambula Project where it will earn up to 51% of the project. Dart Mining’s current plan across its Queensland projects includes:

• Complete the review of CBADD011 through CBADD013 assays that have been received and are currently in QAQC by the Dart Mining Competent Person;

• Update and improve Coonambula drill hole programme to complete the 4,000m drilling;

• Finalise the Native Title compensation agreement for Skarn Ridge (EPMA28868);

• Complete the review of IP data from Coonambula and plan second stage drilling as part of the Coonambula earn-in agreement with ASX:GDM;

• Undertake further desktop studies and spectral interpretation of the Skarn Ridge project to develop Dart Mining's first phase exploration programme;

• Plan for and collect any outstanding data to support a maiden Mineral Resource Estimate at the Coonambula Project (including metallurgical test work, density characterisation and exploration data analysis);

• Plan follow up exploration programmes for the Triumph Project to expand the existing Mineral Resource and test new targets; and

• Receive assays and report on surface sampling at selected Triumph historical mines including Advance (the most productive historical mine), Chandlers and Sailor Boy (all three mines are not part of the current MRE).

Approved for release by the Board of Directors.

For more information contact:

James Chirnside Terry Bates Managing Director Director Dart Mining NL Dart Mining NL jchirnside@dartmining.com.au tbates@dartmining.com.au +61 419 605 842 InvestorHub Link

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COONAMBULA ANTIMONY-GOLD PROJECT

The Coonambula Antimony-Gold Project ( Coonambula or Project ) is located approximately 390km by road north-northwest of Brisbane, Queensland. Coonambula is 70km southeast of the multimillion-ounce Cracow gold mine and 25km southwest of the Eidsvold goldfield (Figure 7). The Project is comprised of five granted Exploration Permits: EPM 15203, EPM 16216, EPM 25260, EPM 26743 and EPM 28433 covering 282 sq.km., and application EPM 29186 covering an area of 227sq.km.

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Figure 7 : Project Location Plan.

Geology – New England Fold Belt geology hosts high grade quartz veins containing Sb-Au at Hillgrove and Wild Cattle Creek in NSW, and Antimony at Neardie near Gympie QLD. Mineralisation at Coonambula is hosted within intrusive granodiorites and holds the potential to host a large intrusion related gold system, with attractive magnetic signature and structural geology.

Two distinct types of reef mineralisation occur: Gold associated with arsenopyrite in quartz and high-grade antimony with calcite in quartz. Disseminated stibnite is recorded in the gold lodes (Malnic, 1985).

Banshee is one of the largest historical antimony mining complexes in Central Queensland, located 70km Southeast of the Cracow gold mine and 25km SW of Eidsvold. Banshee is a historic highgrade direct shipping ore antimony mine (worked variously between 1876 and 1983, The Banshee

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Mine when reopened in 1983 produced 20t of ore containing 4t of Antimony ( GDM Prospectus 2023 ). 12 RC and 1 diamond drill hole have been drilled over 650m of strike length at Banshee.

Directly east of Banshee lies another Antimony-Gold prospect called Lady Mary (previously called Lady May). This prospect lies 1km along strike from Banshee, potentially along the same E-W Banshee structure. Surface rock chip samples from old mine dumps at Lady Mary have returned up to 49.6% Sb and 1.3 g/t Au ( GDM Sep 2024 ). The area between Banshee and Lady Mary has not yet been explored and is a high priority target being assessed by the current IP survey.

The Perseverance mine was mined to 132m depth with mining widths up to 10m wide ( GDM Prospectus 2023 ). Past production of gold from the mine was reported as 20kt @ 20g/t Au (Malnic, 1985) however only 3 drill holes have been completed to date.

Total strike of the prospective antimony zone is approximately 5km with historic mines either side of Banshee. Lady Mary located 900m east of Banshee with additional historic mines occurring some 3km west of Banshee giving a potential E-W strike of 5km. Individual high grade antimony shoots are interpreted as having a strike length of 30-100m each based upon Banshee drilling where 3 shoots of this length exist in the central core zone.

In GDM’s 2023 prospectus ( GDM Prospectus 2023 ) consulting company Derisk stated that it: “ Considers that the Coonambula project tenements are prospective for mesothermal vein and stockwork gold and gold-antimony deposits, as well as intrusion-related and epithermal gold deposits. Most work at this project has focused on areas in and around historical mine workings. Derisk considers there is potential to define extensions or repetitions of known mineralisation at some of the historical workings. There is also potential to discover new mineralisation but exploration for these targets is at a very early stage. ”

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Figure 8 : Banshee mine waste dump material observed (unsampled) by Dart Mining in January 2025 showing antimony mineral (70% stibnite) with encasing vein quartz.

*Visual estimates of mineral abundance should never be considered a proxy or substitute for laboratory analyses where concentrations or grades are the factor of principal economic interest. Visual estimates also potentially provide no information regarding impurities or deleterious physical properties relevant to valuations

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Figure 9: Coonambula geology and key prospects.

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About Dart Mining

The Triumph Gold Project is Dart’s first step into an advanced intrusion related gold system project in Queensland. Dart will look to develop a regional presence in Queensland through advanced stage intrusion related and epithermal gold projects. Dart is farming into the Coonambula Antimony-Gold Project in Central Queensland. Dart Mining will continue to evaluate several historic goldfields in Central and Northeast Victoria including the Rushworth Goldfield and the new porphyry and lithium province in Northeast Victoria identified by Dart. The area is prospective for precious, base, and strategic metals. Dart Mining has built a strategic and highly prospective gold exploration portfolio in Central and Northeast regions of Victoria, where historic surface and alluvial gold mining indicates the existence of potentially large gold endowment.

Competent Person’s Statement

The information in this report has been prepared, compiled, and verified by Mr Andrew Dawes, who is a Member of the Australasian Institute of Mining and Metallurgy and a Member of the Australian Institute of Geoscientists. Mr Andrew Dawes is employed by AHD Resources and consults to Dart Mining NL. Mr Dawes has sufficient experience that is relevant to the style of mineralisation and type of deposits under consideration and to the activity being undertaken to qualify as a competent person as defined in the 2012 Edition of the “Australasian Code for Reporting of Exploration Results, Mineral Resources and Ore Reserves”. Mr. Dawes takes responsibility for the exploration results, and consents to the inclusion in the report of the matters based on his information in the form and context in which it appears.

Forward-Looking Statement

Certain statements contained in this document constitute forward-looking statements. Forward-looking statements include, but are not limited to, Dart Mining’s current expectations, estimates and projections about the industry in which Dart Mining operates, and beliefs and assumptions regarding Dart Mining’s future performance. Such forward-looking statements are based on a number of estimates and assumptions made by the Company and its consultants in light of experience, current conditions and expectations of future developments which the Company believes are appropriate in the current circumstances. When used in this document, words such as; “anticipate”, “could”, “intends”, “estimate”, “potential”, “plan”, “seeks”, “may”, “should”, and similar expressions are forward-looking statements. Although Dart Mining believes that its expectations presented in these forward-looking statements are reasonable, such statements are subject to known and unknown risks, uncertainties and other factors, which may cause the actual results, achievements and performance of the Company to be materially different from the future results and achievements expressed or implied by such forward-looking statements. Investors are cautioned that forward-looking information is no guarantee of future performance and accordingly, investors are cautioned not to place undue reliance on these forward-looking statements.

No new information has been included in this release, all exploration results have been previously reported by Great Divide Mining (ASX: GDM) and are available on their website. Dart Mining is not aware of any new information or data that materially affects the information included in the original announcements.

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APPENDIX ONE:

TABLE 1: DRILL HOLE SUMMARY OF REPORTED DRILLING

Hole ID	Easting	Northing	Elevation	Max Depth (m)	Dip (deg)	Azimuth (deg)
CBADD003	291853.4	7173930.0	232.1	170.4	-54.7	153
CBADD004	291920.8	7173907.0	240.7	140.1	-48.7	154
CBADD005	292054.8	7173959.5	239.9	176	-49.4	156
CBADD005a	292058.5	7173949.5	240.3	86	-49.2	153
CBADD006	291848.3	7173863.0	234.6	68.1	-63.8	161
CBADD007	292127.0	7173970.5	237.5	164	-49.3	157
CBADD008	292133.9	7173919.0	239.9	90	-49.8	157
CBADD009	291872.8	7173884.0	233.5	89.2	-59.8	160
CBADD010	291999.9	7173862.0	237.9	82.7	-49.3	342

– TABLE 2 ASSAY RESULTS CBADD003 CBADD013

Hole ID	From (m)	To (m)	Width (m)	Au (g/t)	Ag (g/t)	Sb (ppm)
CBADD003	126.5	127.1	0.6	0.003	0.11	24
CBADD003	127.1	127.5	0.4	0.001	0.04	34.3
CBADD003	127.5	128	0.5	0.002	0.06	9.6
CBADD003	128	128.5	0.5	0.003	0.12	19.95
CBADD003	128.5	129	0.5	0.001	0.05	54.8
CBADD003	129	129.6	0.6	0.008	0.49	87.4
CBADD003	129.6	130.2	0.6	0.01	0.11	111.5
CBADD003	130.2	130.8	0.6	0.009	0.17	134.5
CBADD003	130.8	131.35	0.55	0.146	0.31	99.3
CBADD003	131.35	131.85	0.5	2.74	145	249000
CBADD003	131.85	132.35	0.5	2.03	25.3	4750
CBADD003	132.35	132.65	0.3	1.235	13.1	17400
CBADD003	132.65	133.1	0.45	0.008	0.23	279
CBADD003	133.1	133.6	0.5	0.003	0.11	67.2
CBADD003	133.6	134.2	0.6	0.006	0.24	200
CBADD003	134.2	134.8	0.6	0.001	0.07	19.35
CBADD003	134.8	135.4	0.6	0.002	0.06	13.2
CBADD003	135.4	136	0.6	0.003	0.09	68.9
CBADD003	136	136.5	0.5	0.002	0.07	21.2
CBADD003	136.5	136.9	0.4	0.212	0.32	57.8
CBADD003	143.5	144	0.5	0.631	3.37	72.3
CBADD003	144	144.6	0.6	2.42	5.42	177.5
CBADD003	144.6	145	0.4	0.144	0.15	21.1
CBADD003	152.5	153	0.5	0.007	0.07	37
CBADD003	153	153.5	0.5	0.007	0.06	28.9
CBADD003	153.5	154	0.5	0.002	0.05	37.5
CBADD003	154	154.5	0.5	0.056	0.11	61.3
CBADD003	154.5	155	0.5	0.018	0.09	67.6
CBADD003	155	155.5	0.5	5.22	0.91	68.4
CBADD003	155.5	156	0.5	8.23	0.84	28000
CBADD003	156	156.5	0.5	0.048	0.06	328
CBADD003	156.5	157.1	0.6	0.013	0.06	36.9
CBADD003	157.1	157.65	0.55	0.016	0.07	70.9
CBADD003	157.65	158.2	0.55	0.091	0.07	23.4
CBADD003	159.5	159.8	0.3	0.782	0.65	15.95
CBADD003	164.8	165.1	0.3	0.67	0.46	47.5
CBADD003	11	11.5	0.5	0.005	0.02	100

15 | P a g e

CBADD003	11.5	12	0.5	0.005	0.19	25.3
CBADD003	12	12.6	0.6	0.006	0.13	10.55
CBADD003	15	15.6	0.6	0.002	0.05	2.43
CBADD003	18.2	18.7	0.5	0.001	0.05	1.14
CBADD003	20	20.3	0.3	0.001	0.05	1.86
CBADD003	21.4	21.8	0.4	0.001	0.02	3.06
CBADD003	37.6	37.9	0.3	0.001	0.06	4.78
CBADD003	42.9	43.2	0.3	0.001	0.03	1.49
CBADD003	82.9	83.2	0.3	0.002	0.09	8.12
CBADD003	100.8	101.5	0.7	0.002	0.03	3.68
CBADD003	102.5	103	0.5	0.001	0.06	17.95
CBADD003	103	103.5	0.5	0.714	0.98	75.5
CBADD003	103.5	104	0.5	0.279	0.3	94.4
CBADD003	104	104.5	0.5	0.006	0.06	85.9
CBADD003	104.5	105	0.5	0.003	0.06	114
CBADD003	105	105.5	0.5	0.002	0.06	108.5
CBADD003	105.5	106	0.5	0.005	0.06	167
CBADD003	106	106.5	0.5	0.004	0.05	180.5
CBADD003	106.5	107	0.5	0.003	0.06	102
CBADD003	107	107.7	0.7	0.002	0.06	34.8
CBADD003	107.7	108.3	0.6	0.003	0.06	44.3
CBADD003	108.3	108.8	0.5	0.012	0.06	171
CBADD003	108.8	109.4	0.6	0.005	0.06	43.5
CBADD003	109.4	110	0.6	0.003	0.07	44.3
CBADD003	110	110.4	0.4	0.012	0.14	109.5
CBADD003	110.4	111	0.6	0.014	0.1	104
CBADD003	111	111.5	0.5	0.007	0.07	57.8
CBADD003	111.5	112	0.5	0.001	0.06	26.7
CBADD003	112	112.6	0.6	0.002	0.06	32.9
CBADD003	112.6	113	0.4	0.005	0.07	114.5
CBADD003	113	113.5	0.5	0.008	0.1	71.3
CBADD003	113.5	114	0.5	0.002	0.06	15.7
CBADD003	114	114.5	0.5	0.002	0.06	13.05
CBADD003	114.5	115.1	0.6	0.002	0.06	9.93
CBADD003	115.1	115.6	0.5	0.002	0.05	9.08
CBADD003	115.6	116.2	0.6	0.002	0.06	24.3
CBADD003	116.2	116.7	0.5	0.017	0.09	132
CBADD003	116.7	117.2	0.5	0.004	0.07	46.1
CBADD003	117.2	117.7	0.5	0.002	0.06	74.1
CBADD003	117.7	118.2	0.5	0.002	0.06	50.2
CBADD003	118.2	118.7	0.5	0.003	0.05	81.3
CBADD003	118.7	119.2	0.5	0.004	0.03	161.5
CBADD003	119.2	119.7	0.5	0.002	0.05	20.3
CBADD004	5	6	1	0.004	0.04	66.3
CBADD004	41.4	41.7	0.3	0.002	0.04	39.7
CBADD004	73.6	74	0.4	0.002	0.05	13.45
CBADD004	74	74.5	0.5	0.002	0.07	16.6
CBADD004	74.5	75	0.5	0.002	0.07	17.7
CBADD004	75	75.5	0.5	0.002	0.05	13.5
CBADD004	75.5	76	0.5	0.002	0.04	15.1
CBADD004	76	76.5	0.5	0.002	0.05	15.65
CBADD004	76.5	77	0.5	0.002	0.05	17.05
CBADD004	77	77.5	0.5	0.001	0.05	143
CBADD004	77.5	78	0.5	0.001	0.05	147
CBADD004	78	79	1	0.003	0.05	115.5
CBADD004	94.7	95.2	0.5	0.001	0.05	17.9
CBADD004	95.2	95.7	0.5	0.001	0.06	14.75
CBADD004	95.7	96.2	0.5	0.002	0.05	13.95
CBADD004	110.7	111.2	0.5	0.003	0.04	9.05
CBADD004	111.2	111.7	0.5	0.001	0.07	15.65
CBADD004	112.2	112.7	0.5	0.002	0.04	11.4
CBADD004	112.7	113.2	0.5	0.002	0.05	11.45

16 | P a g e

CBADD004	113.2	113.7	0.5	0.002	0.05	13.05
CBADD004	113.7	114.2	0.5	0.001	0.06	11.85
CBADD004	114.2	114.7	0.5	0.001	0.05	13.1
CBADD004	132.8	133.1	0.3	0.001	0.05	3.48
CBADD004	139.6	140.1	0.5	0.002	0.02	1.88
CBADD004	51.3	51.8	0.5	0.002	0.05	77.8
CBADD004	51.8	52.3	0.5	0.002	0.06	27.8
CBADD004	52.3	52.8	0.5	0.002	0.06	28.3
CBADD004	52.8	53.3	0.5	0.195	0.29	62.3
CBADD004	53.3	53.8	0.5	6.18	1.15	730
CBADD004	53.8	54.3	0.5	0.016	0.06	94.9
CBADD004	54.3	54.7	0.4	0.088	0.11	67.5
CBADD004	54.7	55.2	0.5	0.043	0.15	84.8
CBADD004	55.2	56	0.8	0.004	0.05	131
CBADD004	56	56.5	0.5	0.002	0.06	120
CBADD004	56.5	57	0.5	0.351	0.38	130.5
CBADD004	57	57.5	0.5	0.113	0.08	101
CBADD004	57.5	57.95	0.45	1.27	0.99	251
CBADD004	57.95	58.58	0.63	2.45	234	17600
CBADD004	58.58	59.1	0.52	1.41	2.9	222
CBADD004	59.1	59.6	0.5	1.055	1.4	172
CBADD004	59.6	60.1	0.5	0.086	0.15	107.5
CBADD004	60.1	60.6	0.5	0.087	0.13	78.3
CBADD004	60.6	61.3	0.7	0.004	0.27	44.3
CBADD004	61.3	62	0.7	0.002	0.09	46.9
CBADD004	62	62.5	0.5	0.002	0.06	74.2
CBADD004	62.5	63	0.5	0.075	0.12	74.1
CBADD004	63	63.5	0.5	0.003	0.06	43.7
CBADD004	63.5	64	0.5	0.202	0.4	94.6
CBADD004	64	64.6	0.6	4.54	6.95	56000
CBADD004	64.6	65.1	0.5	3.41	1.59	334
CBADD004	65.1	65.6	0.5	0.021	0.08	188.5
CBADD004	65.6	66.1	0.5	0.013	0.09	251
CBADD004	66.1	66.6	0.5	1.79	1.18	118.5
CBADD004	66.6	67.1	0.5	1.815	1.59	1295
CBADD004	67.1	68	0.9	0.006	0.06	28.1
CBADD004	68	68.5	0.5	0.008	0.07	11.95
CBADD004	68.5	69	0.5	0.004	0.05	12.85
CBADD005	12.7	13.2	0.5	0.002	0.03	4.37
CBADD005	15.5	16.3	0.8	0.003	0.06	5.17
CBADD005	29.7	30	0.3	0.002	0.12	4.68
CBADD005	46.35	46.68	0.33	0.001	0.04	1.64
CBADD005	81	81.5	0.5	0.001	0.05	4.2
CBADD005	81.5	82	0.5	0.008	0.06	7.2
CBADD005	82	82.5	0.5	0.001	0.05	15.9
CBADD005	82.5	82.9	0.4		0.07	78.5
CBADD005	82.9	83.2	0.3	0.289	0.56	72.9
CBADD005	83.2	83.7	0.5	1.305	10.95	249
CBADD005	84.6	85.1	0.5	10.05	1.32	55.7
CBADD005	85.1	85.5	0.4	6.18	4.3	10000
CBADD005	85.5	86	0.5	2.39	1.53	139.5
CBADD005	86	86.6	0.6	0.053	0.13	72.3
CBADD005	86.6	87.1	0.5	0.031	0.08	63.5
CBADD005	87.1	87.7	0.6	0.009	0.05	10.35
CBADD005	87.7	88.7	1	0.002	0.07	8.73
CBADD005	88.7	89.7	1	0.002	0.06	9.95
CBADD005	89.7	90.2	0.5	0.002	0.05	13.8
CBADD005	90.2	90.8	0.6	0.004	0.05	14.5
CBADD005	90.8	91.4	0.6	0.004	0.04	24.1
CBADD005	91.4	92	0.6	0.002	0.06	42.2
CBADD005	92	92.73	0.73	0.004	0.08	59.4
CBADD005	100.5	100.8	0.3	0.001	0.03	14.9

17 | P a g e

CBADD005	126.5	127.3	0.8		0.05	7.15
CBADD005	127.3	128	0.7	0.001	0.04	4.86
CBADD005	128	129	1	0.001	0.04	6.68
CBADD005	133	133.9	0.9	0.001	0.04	22.3
CBADD005	133.9	134.9	1	0.001	0.06	37.1
CBADD005	134.9	135.7	0.8	0.01	0.05	26.3
CBADD005	135.7	136	0.3	4.67	0.8	9050
CBADD005	136	136.7	0.7	0.081	0.08	64.2
CBADD005	144.7	145.3	0.6	0.004	0.05	47.8
CBADD005	145.3	146	0.7	0.016	0.05	39.7
CBADD005	146	146.7	0.7	0.002	0.03	7.05
CBADD005	146.7	147	0.3	0.003	0.07	2.91
CBADD005	172	173	1	0.001	0.04	4.09
CBADD005a	66	66.5	0.5	0.001	0.05	9.19
CBADD005a	66.5	67	0.5	0.001	0.05	17.9
CBADD005a	67	67.7	0.7		0.06	35.3
CBADD005a	67.7	68.5	0.8	0.417	0.59	116
CBADD005a	68.5	69.4	0.9	0.543	0.86	147
CBADD005a	69.4	69.8	0.4	2.9	3.28	69900
CBADD005a	69.8	70.3	0.5	1.605	1.66	556
CBADD005a	70.3	71	0.7	0.047	0.22	155.5
CBADD005a	71	72	1	0.504	0.56	193.5
CBADD005a	72	73	1	0.014	0.09	96.3
CBADD005a	73	73.7	0.7	0.47	0.99	87.3
CBADD005a	73.7	74.5	0.8	1.855	2.15	72.8
CBADD005a	74.5	75	0.5	0.528	0.52	304
CBADD005a	75	75.5	0.5	1.33	2.34	165.5
CBADD005a	75.5	76	0.5	0.531	1.14	145.5
CBADD005a	76	76.5	0.5	1.2	1.23	56.6
CBADD005a	76.5	77	0.5	0.009	0.06	14.65
CBADD005a	77	78	1	0.002	0.05	10.05
CBADD005a	78	79	1	0.002	0.05	6.6
CBADD005a	79	79.6	0.6	0.002	0.04	10.05
CBADD005a	79.6	80.3	0.7	0.001	0.05	4.88
CBADD005a	80.3	80.7	0.4	0.001	0.02	11.8
CBADD005a	80.7	81.7	1	0.001	0.05	6.24
CBADD005a	81.7	82.7	1	0.001	0.05	5.84
CBADD005a	82.7	83.6	0.9	0.002	0.04	20.8
CBADD005a	83.6	84.1	0.5	0.001	0.04	4.55
CBADD005a	84.1	85	0.9	0.001	0.04	25.7
CBADD005a	85	86	1	0.002	0.03	29.1
CBADD006	3	4	1	0.016	0.07	112
CBADD006	4	5	1	0.004	0.05	65.1
CBADD006	5	6	1	0.003	0.09	72.8
CBADD006	6	7	1	0.004	0.06	74.1
CBADD006	7	7.9	0.9	0.014	0.07	76.2
CBADD006	7.9	8.7	0.8	0.342	0.32	1400
CBADD006	8.7	9.5	0.8	4.85	181	60300
CBADD006	9.5	10	0.5	2.11	53.3	176500
CBADD006	10	11	1	0.088	0.33	1430
CBADD006	11	12	1	0.005	0.16	354
CBADD006	12	13	1	0.003	0.11	83.3
CBADD006	13	14	1	0.002	0.16	46.1
CBADD006	14	15	1	0.002	0.08	40.1
CBADD007	34.2	34.7	0.5	0.001	0.08	6.62
CBADD007	57.2	57.7	0.5	0.002	0.05	19.7
CBADD007	95.4	96.4	1	0.002	0.05	2.8
CBADD007	96.4	97.4	1	0.003	0.06	10.65
CBADD007	97.4	98	0.6	0.004	0.03	8.49
CBADD007	98	99	1	0.002	0.04	7.91
CBADD007	99	100	1	0.002	0.05	20.8
CBADD007	100	101	1	0.003	0.06	29.9

18 | P a g e

CBADD007	101	101.4	0.4	0.002	0.05	30.1
CBADD007	101.4	102	0.6	0.002	0.06	5.48
CBADD007	102	103	1	0.001	0.06	8.5
CBADD007	103	103.6	0.6	0.002	0.05	11.8
CBADD007	103.6	104.4	0.8	0.002	0.05	11.2
CBADD007	104.4	105	0.6	0.222	0.45	36
CBADD007	105	105.7	0.7	0.002	0.07	6.63
CBADD007	105.7	106	0.3	0.002	0.05	3.46
CBADD007	106	106.7	0.7	0.003	0.05	4.95
CBADD007	106.7	107.7	1	0.002	0.05	14.6
CBADD007	107.7	108.4	0.7	0.83	0.48	38.4
CBADD007	108.4	109.4	1	0.009	0.05	14.65
CBADD007	109.4	110	0.6	0.002	0.05	6.52
CBADD007	110	111	1	0.003	0.04	17.7
CBADD007	111	112	1	0.001	0.05	16.7
CBADD007	112	113	1	0.002	0.02	6.83
CBADD007	125	125.5	0.5	0.002	0.05	3.41
CBADD007	125.5	126	0.5	0.003	0.06	2.92
CBADD007	126	126.5	0.5	0.003	0.09	1.94
CBADD007	126.5	127	0.5	0.002	0.05	1.77
CBADD007	127	127.5	0.5	0.002	0.07	1.6
CBADD007	127.5	128.2	0.7	0.002	0.07	5.69
CBADD007	128.2	128.9	0.7	0.002	0.04	10.8
CBADD007	128.9	129.9	1	0.003	0.04	2.84
CBADD007	129.9	130.5	0.6	0.001	0.05	3.84
CBADD007	137	138	1	0.001	0.05	2.31
CBADD007	138	139	1	0.001	0.04	3.9
CBADD007	139	139.8	0.8	0.002	0.04	9.94
CBADD007	139.8	140.5	0.7	2.83	0.59	73.1
CBADD007	140.5	141.1	0.6	1.3	1.04	374
CBADD007	141.1	141.5	0.4	8.25	3.5	154500
CBADD007	141.5	141.9	0.4	1.745	0.81	164
CBADD007	141.9	142.5	0.6	0.024	0.05	185.5
CBADD007	142.5	143.4	0.9	0.004	0.05	98.4
CBADD007	143.4	144	0.6	0.002	0.04	51.4
CBADD007	144	145	1	0.002	0.05	28.2
CBADD007	145	146	1	0.001	0.03	27.4
CBADD007	146	146.9	0.9	0.001	0.05	6.35
CBADD007	146.9	147.9	1	0.014	0.06	44.3
CBADD007	147.9	148.4	0.5	0.001	0.04	9.07
CBADD007	148.4	149	0.6	0.001	0.05	4.11
CBADD007	149	149.6	0.6	0.001	0.04	3.83
CBADD007	149.6	150.5	0.9	0.001	0.05	6.76
CBADD007	150.5	151	0.5	0.001	0.05	2.29
CBADD008	9	10	1	0.004	0.07	5.57
CBADD008	10	11	1	0.036	0.18	5.27
CBADD008	11	12	1	0.227	0.27	6.98
CBADD008	12	13	1	0.303	0.15	16.05
CBADD008	13	14	1	0.003	0.05	4.78
CBADD008	14	15	1	0.001	0.06	5.08
CBADD008	15	16	1	0.014	0.08	6.7
CBADD008	16	17	1	0.001	0.05	8.91
CBADD008	17	18	1	0.057	0.05	6.96
CBADD008	18	19	1		0.03	2.21
CBADD008	23.5	23.8	0.3	0.223	0.19	19.9
CBADD008	23.8	24.8	1	0.001	0.04	1.92
CBADD008	24.8	25.5	0.7	0.001	0.06	1.4
CBADD008	25.5	26.5	1	0.001	0.07	3.39
CBADD008	26.5	27.5	1		0.06	3.27
CBADD008	27.5	28	0.5	0.003	0.09	10.2
CBADD008	28	28.4	0.4		0.04	7.69
CBADD008	28.4	29.2	0.8	0.01	0.14	11.25

19 | P a g e

CBADD008	29.2	29.6	0.4		0.06	3
CBADD008	29.6	30.2	0.6	0.008	0.06	3.88
CBADD008	30.2	31	0.8		0.05	0.78
CBADD008	31	32	1		0.04	1.12
CBADD008	32	33	1	0.003	0.06	2
CBADD008	33	34	1	0.003	0.05	1.52
CBADD008	34	34.7	0.7		0.06	2.64
CBADD008	34.7	35.7	1	0.109	0.15	11.05
CBADD008	35.7	36.2	0.5	0.013	0.06	5.07
CBADD008	36.2	37	0.8	0.004	0.05	2.47
CBADD008	37	37.8	0.8	0.012	0.05	6.61
CBADD008	37.8	38.7	0.9	0.007	0.07	8.17
CBADD008	42.2	43.2	1		0.04	19.5
CBADD008	43.2	44	0.8		0.04	8.78
CBADD008	52	53	1		0.04	2.46
CBADD008	53	54	1		0.04	4.32
CBADD008	54	55	1		0.03	2.53
CBADD008	55	56	1	0.003	0.03	4.5
CBADD008	56	57	1	0.007	0.06	25.1
CBADD008	57	58	1	0.003	0.05	23.2
CBADD008	58	59	1	0.002	0.04	6.42
CBADD008	63	63.7	0.7	0.008	0.05	5.02
CBADD008	72	73	1		0.13	6.74
CBADD008	73	74	1	0.003	0.13	7.87
CBADD008	74	74.5	0.5	0.001	0.03	8.2
CBADD008	74.5	75	0.5		0.05	13.1
CBADD008	75	76	1	0.003	0.03	14.25
CBADD008	76	77	1	0.002	0.02	11.4
CBADD008	77	77.5	0.5		0.02	14.4
CBADD008	77.5	78.5	1	0.001	0.03	12.15
CBADD008	78.5	79.5	1		0.04	4.51
CBADD008	79.5	80.1	0.6	0.001	0.1	29.5
CBADD008	80.1	80.5	0.4	4.51	1.07	46.6
CBADD008	80.5	81.2	0.7	0.205	0.29	44.5
CBADD008	81.2	82	0.8	0.013	0.03	31.2
CBADD008	82	83	1	0.001	0.04	22
CBADD008	83	84	1	0.001	0.04	15.15
CBADD008	84	84.8	0.8	0.001	0.02	12.45
CBADD008	84.8	85.7	0.9		0.03	3.42
CBADD008	85.7	86.2	0.5		0.03	2.2
CBADD009	3.4	3.7	0.3	0.006	0.2	365
CBADD009	3.7	4.6	0.9	0.004	0.07	306
CBADD009	4.6	5.6	1	0.002	0.04	101
CBADD009	5.6	6.6	1	0.001	0.06	90
CBADD009	6.6	7.6	1	0.001	0.05	56.3
CBADD009	7.6	8.6	1	0.001	0.04	36.8
CBADD009	8.6	9.6	1		0.06	53.2
CBADD009	9.6	10.6	1		0.05	28.6
CBADD009	10.6	11.6	1		0.04	28.5
CBADD009	11.6	12.5	0.9	0.002	0.02	38.7
CBADD009	12.5	13.1	0.6		0.05	49.8
CBADD009	13.1	14	0.9		0.05	24.2
CBADD009	14	15	1	0.001	0.05	41.6
CBADD009	15	16	1		0.05	15.8
CBADD009	16	17	1		0.05	23
CBADD009	17	17.5	0.5	0.001	0.03	104.5
CBADD009	17.5	18	0.5		0.01	78.5
CBADD009	22	22.6	0.6		0.04	18.1
CBADD009	22.6	23.2	0.6		0.05	17.7
CBADD009	35.2	35.5	0.3		0.02	15.05
CBADD009	35.5	36	0.5	0.014	0.05	11.15
CBADD009	36	36.6	0.6	0.005	0.04	16.2

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CBADD009	36.6	37.2	0.6	0.013	0.07	33
CBADD009	37.2	37.9	0.7	0.001	0.05	25.2
CBADD009	37.9	38.9	1		0.06	49.7
CBADD009	38.9	39.9	1		0.05	45.3
CBADD009	39.9	40.6	0.7		0.04	69.1
CBADD009	40.6	41.4	0.8	0.014	0.09	121
CBADD009	41.4	42.2	0.8	0.006	0.06	132.5
CBADD009	42.2	43.2	1	0.007	0.06	117.5
CBADD009	43.2	43.6	0.4	4.86	2.76	11600
CBADD009	43.6	44.1	0.5	13.1	1.85	227
CBADD009	44.1	44.6	0.5	1.225	0.96	89
CBADD009	44.6	45.1	0.5	3.06	0.75	160
CBADD009	45.1	45.6	0.5	2.85	2.1	72.8
CBADD009	45.6	46.1	0.5	0.552	1.31	973
CBADD009	46.1	46.4	0.3	4.02	27.6	13200
CBADD009	46.4	47	0.6	1.585	1.46	187.5
CBADD009	47	47.5	0.5	2.05	0.95	262
CBADD009	47.5	48.5	1	0.018	0.06	32.3
CBADD009	48.5	49.5	1	0.005	0.06	11.95
CBADD009	49.5	50.5	1	0.006	0.05	18.35
CBADD009	50.5	51	0.5	0.19	0.09	25.8
CBADD009	51	51.5	0.5	0.036	0.13	32.6
CBADD009	51.5	52	0.5	0.073	0.19	47.4
CBADD009	52	52.5	0.5	0.001	0.06	23.3
CBADD009	52.5	53	0.5	0.001	0.06	10.45
CBADD009	53	54	1	0.001	0.05	5.12
CBADD009	54	55	1	0.002	0.05	5.17
CBADD009	55	56	1		0.04	5.4
CBADD009	58.3	59.3	1	0.003	0.04	5.3
CBADD010	12	13	1	0.004	0.08	80.2
CBADD010	13	13.5	0.5	0.027	0.39	213
CBADD010	13.5	14.1	0.6	2.41	2.12	199
CBADD010	14.1	14.3	0.2	3.26	1.84	125.5
CBADD010	14.3	15.3	1	0.077	0.28	441
CBADD010	15.3	16	0.7	0.008	0.1	39.9
CBADD010	16	17	1	0.006	0.08	16.85
CBADD010	17	18	1	0.001	0.05	14.7
CBADD010	22	23	1	0.002	0.06	60.8
CBADD010	23	24	1	0.002	0.07	73.8
CBADD010	24	25	1	0.003	0.08	72
CBADD010	25	26	1	0.002	0.04	45.9
CBADD010	26	27	1	0.001	0.04	39.1
CBADD010	27	28	1	0.001	0.05	44.2
CBADD010	28	29	1		0.05	86.7
CBADD010	29	30	1	0.001	0.06	47.2
CBADD010	30	31	1	0.001	0.05	31.9
CBADD010	31	32	1	0.001	0.07	63.4
CBADD010	32	32.5	0.5	0.001	0.07	44.6
CBADD010	32.5	32.8	0.3	1.8	3.24	884
CBADD010	32.8	33.3	0.5	1.36	1.58	501
CBADD010	33.3	34.3	1	0.158	0.95	237
CBADD010	34.3	35.3	1	0.686	1	280
CBADD010	35.3	36.2	0.9	0.034	1.64	328
CBADD010	36.2	36.5	0.3	2.91	2.93	259
CBADD010	36.5	36.7	0.2	8.67	3.26	3130
CBADD010	36.7	37.7	1	2.56	100	218000
CBADD010	37.7	37.9	0.2	20.2	10.8	40100
CBADD010	37.9	38.5	0.6	1.615	17.2	446000
CBADD010	38.5	39	0.5	3.21	3.23	5050
CBADD010	39	39.5	0.5	10.75	3.43	47200
CBADD010	39.5	40	0.5	3.84	4.67	604
CBADD010	40	40.5	0.5	4	51.6	409

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CBADD010	40.5	41.5	1	0.82	0.51	769
CBADD010	41.5	42	0.5	0.064	0.34	1160
CBADD010	42	43	1	0.014	0.22	233
CBADD010	43	44	1	0.01	0.21	693
CBADD010	44	45	1	0.019	0.33	1560
CBADD010	45	46	1	0.006	0.12	253

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APPENDIX TWO

JORC Code, 2012 Edition – Table 1 report template Section 1 Sampling Techniques and Data

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

Criteria	JORC Code explanation	Commentary	Commentary
Sampling	• Nature and quality of sampling (eg cut	•	Sampling has been made on NQ
techniques	channels, random chips, or specific		diamond drilled core.
	specialised industry standard measurement tools appropriate to the minerals under investigation, such as down hole gamma sondes, or handheld	•	Sampling is half core sampling based on the geologist’s sub sampling (down to 30cm) logging
	XRF instruments, etc). These examples		definition.
	should not be taken as limiting the broad	•	Samples are prepared with PREP-
	meaning of sampling.		31B which includes crush to 70 %
	• Include reference to measures taken to ensure sample representivity and the appropriate calibration of any measurement tools or systems used.		passing 2mm, riffle split off 1kg, pulverise split to better than 85% passing 75 microns.
	• Aspects of the determination of
	mineralisation 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 pulverised 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
	mineralisation types (eg submarine
	nodules) may warrant disclosure of
	detailed information.
Drilling	• Drill type (eg core, reverse circulation,	•	Drilling is diamond drilling NQ core
techniques	open-hole hammer, rotary air blast, auger, Bangka, sonic, etc) and details (eg core diameter, triple or standard tube, depth of diamond tails, face-		size and is triple tube drilling. Core is oriented where possible using the Reflex ACT III tool.
	sampling bit or other type, whether core
	is oriented and if so, by what method,
	_etc). _
Drill	• Method of recording and assessing core	•	Core is measured after each run
sample recovery	and chip sample recoveries and results assessed.		and core recovery based on the drill metres is recorded.
	• Measures taken to maximise sample recovery and ensure representative nature of the samples.	•	Once in the transition and fresh material, Triumph experiences
	• Whether a relationship exists between		limited to no core loss with the
	sample recovery and grade and whether		exception of intensely broken
	sample bias may have occurred due to		zones where recovery is still > 95%.
	preferential loss/gain of fine/coarse material.	•	No relationship has been observed between sample recovery and gold
			grade.
Logging	• Whether core and chip samples have	•	The drill core has been geologically
	been geologically and geotechnically logged to a level of detail to support		and geotechnically logged to a level to support appropriate mineral

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Criteria	JORC Code explanation	Commentary	Commentary
	appropriate Mineral Resource		resource estimation, mining studies
	estimation, mining studies and metallurgical studies. • Whether logging is qualitative or quantitative in nature. Core (or costean, channel, etc) photography.		and metallurgical studies. Core is logged both qualitatively and quantitatively. Core tray photography is both wet and dry
	• The total length and percentage of the		photography.
	relevant intersections logged.	•	Sampling is discrete based on
			observed mineralisation, alteration,
			keystructural features.
Sub-	• If core, whether cut or sawn and whether	•	Core is cut to ½ core before being
sampling techniques and sample preparation	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	•	dispatched to the laboratory. The PREP-31B method includes crush to 70 % passing 2mm, riffle split off 1kg, pulverise split to better than 85% passing 75
	preparation technique.		microns. The larger 1kg riffle split is
	• Quality control procedures adopted for		larger than the standard 250g to
	all sub-sampling stages to maximise representivity of samples. • Measures taken to ensure that the sampling is representative of the in situ material collected, including for instance	•	reduce sample size bias. Sampling size is suitable to represent the mineralisation intersected.
	results for field duplicate/second-half
	sampling.
	• Whether sample sizes are appropriate to
	the grain size of the material being
	sampled.
Quality of	• The nature, quality and appropriateness	•	All samples were analysed at ALS
assay data and laboratory tests	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	•	Global (ALS, Brisbane). All samples were assayed for Au using a 50g fire assay with AU- ICP22 determination as well as ME-
	parameters used in determining the		MS61 for multi element. In the case
	analysis including instrument make and		where key elements are over range,
	model, reading times, calibrations factors applied and their derivation, etc. • Nature of quality control procedures adopted (eg standards, blanks, duplicates, external laboratory checks)		Ag, Pb, Zn, and Cu was completed using OG-62. As completed with OG46, and Au completed with GRA22. Sb completed with XRF15c
	and whether acceptable levels of		and Hg completed with MS42.
	accuracy (ie lack of bias) and precision	•	The three types of QAQC samples
	have been established.		were used were Certified Reference
			Material (CRM/Standards), Field
			Duplicates, and Blank material.
		•	The Blanks consist of store-bought
			sand which has been shown to be
			barren based on previous work.
			The Blanks are used to provide
			information of any possible
			contamination or calibration issues
			during the crush, pulverisation, and
			analytical phases. The field
			duplicates utilised the spear to
			collect a second sample to test
			repeatability (precision) of the
			original sample. The standards

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Criteria	JORC	Code explanation	Commentary	Commentary
				samples are used to test the
				accuracy of the analyses.
			•	Three CRMs were OREAS standards
				and include: OREAS 277, OREAS
				245, and OREAS 233.
			•	QAQC samples were entered into
				the sample stream at a rate of 1 in
				20.
			•	Where lower detection limits were
				reported for assay results these
				were replaced by half the lower
				detection limit for geological
				interpretation and modelling
				purposes.
Verification	•	The verification of significant	•	All core photos are reviewed by the
of sampling and assaying	• •	intersections by either independent or alternative company personnel. The use of twinned holes. Documentation of primary data, data entry procedures, data	•	Competent Person and also visited site during early drilling. No twinned holes have been undertaken.
		verification, data storage (physical	•	Data from the field log sheets is
		and electronic) protocols.		entered into a digital database,
	•	Discuss any adjustment to assay		primarily an Excel spreadsheet with
		data.		subsequent conversion into an SQL
				database maintained by EarthSQL
				at the completion of the hole. The
				Excel spreadsheet has been created
				with a series of validation criteria in
				the form of pulldown menus for
				each data entry that restricts what
				can be entered into each field and
				significantly reduces the error
				associated with data entry.
			•	Assay results are received from the
				laboratory in electronic (via email)
				format onsite and sent to Sample
				Data importing to the EarthSQL
				database. The electronic results are
				provided in an CSV file.
Location of	•	Accuracy and quality of surveys	•	Collars are collected by Dart
data points		used to locate drill holes (collar and down-hole surveys), trenches, mine workings and other locations used in Mineral Resource estimation.		Geologists using a dGPS Trimble device and is suitable for collecting collar XYZ.
	•	Specification of the grid system	•	All collar coordinates are in MGA94
		used.		Z56.
	•	Quality and adequacy of	•	Downhole survey has been
		topographic control.		surveyed using Reflex survey tool.
Data	•	Data spacing for reporting of	•	Report is of a single drill hole and
spacing and distribution	•	Exploration Results. Whether the data spacing and distribution is sufficient to establish the degree of geological and grade continuity appropriate for the	•	spacing is not relevant. Proximity to historical holes is within 40m and intercepts show good correlation with respect to
		Mineral Resource and Ore Reserve		alteration andgrade(Au,Ag,and

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Criteria	JORC	Code explanation	Commentary	Commentary
		estimation procedure(s) and		Sb).
	•	classifications applied. Whether sample compositing has been applied.	•	Samples have not been composited.
Orientation	•	Whether the orientation of sampling	•	Drilling is typically orientated
of data in relation to geological structure	•	achieves unbiased sampling of possible structures and the extent to which this is known, considering the deposit type. If the relationship between the	•	perpendicular to the interpreted strike of mineralization where possible. Observations of the structural
		drilling orientation and the		logging highlight all striking
		orientation of key mineralised		mineralised veins and top and
		structures is considered to have		bottom orientations of the stibnite
		introduced a sampling bias, this should be assessed and reported if		veins was able to be collected.
		material.
Sample	•	The measures taken to ensure	•	Samples are under the care of Dart
security		sample security.		Geologists from logging through to
				deliveryto ALS in Brisbane.
Audits or	•	The results of any audits or reviews	•	No external reviews of audits on
reviews		of sampling techniques and data.		this drilling have been completed.
				Drilling has been reviewed
				internally within Dart.

Section 2 Reporting of Exploration Results

(Criteria listed in the preceding section also apply to this section.)

Criteria	JORC	Code explanation	Commentary	Commentary
Mineral	•	Type, reference name/number,	•	The Coonambula Project consists
tenement and land tenure status		location and ownership including agreements or material issues with third parties such as joint ventures, partnerships, overriding royalties, native title interests,		of five contiguous Queensland exploration permits for minerals (EPMs): o EPM 15203 (Widbury),
		historical sites, wilderness or		o EPM 16216 (Lady
		national park and environmental		Margaret),
		settings.		o EPM 25260
	•	The security of the tenure held at the time of reporting along with any known impediments to obtaining a licence to operate in		(Coonambula), o EPM 26743 (Eidsvold), and
		the area.		o EPM 28433 (Coonambula
				Extended).
			•	Each of the granted Coonambula
				tenements is currently held 100%
				by wholly owned subsidiaries of
				Great Divide Mining Ltd (GDM),
				namely GDM Coonambula Pty Ltd
				and GDM Yellow Jack Pty Ltd. Dart
				Mining Ltd has a joint venture
				agreement (Coonambula Joint
				Venture) to complete exploration
				works on the EPMs.
Exploration	•	Acknowledgment and appraisal of	•	Historical exploration in the
done by other		exploration by other parties.		Coonambula area has been
parties				undertaken bya number of

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Criteria	JORC	Code explanation	Commentary	Commentary
				parties since the 1970s, primarily
				targeting epithermal-style gold
				and base metal mineralisation.
			•	Work included regional geological
				mapping, soil and rock chip
				geochemistry, and limited
				geophysical surveys. More
				detailed exploration was carried
				out in the early 2000s by junior
				explorers, with emphasis on gold
				and antimony mineralisation
				associated with quartz veining.
			•	In 2013–2014, drilling programs
				were completed at the Banshee
				prospect under the direction of
				Paul Byrne. These programs
				tested near-surface quartz–
				sulphide veining and returned
				anomalous gold and antimony
				results.
			•	Data from these programs,
				including drill collar locations,
				assay results, and geological logs
				which were reported to the ASX
				by GDM
			•	Trenching programs were
				completed across the Banshee
				prospect to test surface
				geochemical anomalies and
				quartz–sulphide veining. These
				trenches exposed mineralised
				structures and returned
				anomalous gold and antimony
				values, providing key targets for
				subsequent drilling. The trenches
				themselves are historic
				(pre‑GDM), but GDM sampled and
				reported those trenches in 2024.
Geology	•	Deposit type, geological setting	•	The Coonambula Project is
		and style of mineralisation.		located ~25 km southwest of
				Eidsvold in southeast Queensland,
				within the northern New England
				Orogen.
			•	Bedrock geology is dominated by
				Carboniferous to Permian–Triassic
				granitoid intrusions of the
				Rawbelle Batholith, intruding
				older metasedimentary
				sequences.
			•	Mineralisation at the Banshee
				Prospect is hosted within east–
				west trending shear zones and
				lodes developed in and adjacent

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Criteria	JORC	Code explanation	Commentary	Commentary
				to the granitoid intrusives.
			•	The Banshee system is
				characterised by antimony–gold
				(Sb–Au) mineralisation, with
				geological similarities to the
				Hillgrove Sb–Au deposit in New
				South Wales.
			•	Mineralisation occurs as stibnite ±
				quartz veins and breccia zones,
				with associated gold enrichment.
Drill hole	•	A summary of all information	•	Drillhole information has been
Information		material to the understanding of		included in the release in
		the exploration results including a tabulation of the following		Appendix 1.
		information for all Material drill
		holes:
		o easting and northing of
		the drill hole collar
		o elevation or RL (Reduced
		Level – elevation above
		sea level in metres) of the
		drill hole collar
		o dip and azimuth of the
		hole
		o down hole length and
		interception depth
		o 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.
Data	•	In reporting Exploration Results,	•	No data aggregation methods
aggregation methods		weighting averaging techniques, maximum and/or minimum grade		have been applied.
		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.
Relationship	•	These relationships are	•	Mineralisation widths are
between mineralisation widths and intercept lengths	•	particularly important in the reporting of Exploration Results. If the geometry of the mineralisation with respect to the drill hole angle is known, its nature		reported as the downhole length. Final interpretation and inclusion of sample results will allow for true width calculations to be
		should be reported.

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Criteria	JORC	Code explanation	Commentary	Commentary
	•	If it is not known and only the		applied.
		down hole lengths are reported,
		there should be a clear statement
		to this effect (eg ‘down hole
		_length, true width not known’). _
Diagrams	•	Appropriate maps and sections	•	Included in the body of the
		(with scales) and tabulations of		announcement.
		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.
Balanced	•	Where comprehensive reporting of	•	All mineralisation intersected in
reporting		all Exploration Results is not practicable, representative reporting of both low and high		the completed hole has been included
		grades and/or widths should be
		practiced to avoid misleading
		reporting of Exploration Results.
Other	•	Other exploration data, if	•	No other material data is
substantive exploration		meaningful and material, should be reported including (but not		presented in this announcement.
data		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.
Further work	•	The nature and scale of planned	•	Plans for further work are
		further work (eg tests for lateral		outlined in the body of the
	•	extensions or depth extensions or large-scale step-out drilling). Diagrams clearly highlighting the areas of possible extensions, including the main geological		announcement which include analysis of the drill core and continued drilling of Dart Mining’s planned locations.
		interpretations and future drilling
		areas, provided this information is
		not commercially sensitive.

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