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PERSEUS MINING LIMITED Capital/Financing Update 2021

Apr 7, 2021

46513_rns_2021-04-06_2f488140-0941-4eb5-9450-ac2e3a5acd55.pdf

Capital/Financing Update

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7 April 2021

MARKET RELEASE

Exploration Success for Perseus in Côte d’Ivoire

HIGHLIGHTS

Recent results from Perseus’s exploration programmes in Côte d’Ivoire, demonstrate potential for organic growth of gold inventories across its multi-mine asset portfolio, as follows:

  • Encouraging results at Govisou , 3km from Perseus’s Yaouré Gold Mine , with wide intercepts of shallow gold mineralisation including:

  • YRC1574: 93m @ 2.74 g/t Au from 0m and 24m @ 1.18 g/t Au from 98m

  • YRC1596: 65m @ 2.73 g/t Au from 24m and 35m @ 3.49 g/t Au from 105m

  • YRC1457: 25m @ 3.33 g/t Au from 55m

  • YRC1458: 52m @ 3.02 g/t Au from 28m

  • YRC1573: 92m @ 2.60 g/t Au from 0m

  • YRC1565: 77m @ 2.47 g/t Au from 0m

  • YRC1572: 76m @ 2.40 g/t Au from 8m

Early indications suggest Govisou hosts a ‘pencil- shaped’ plunging structure that remains open at

depth. Follow-up drilling is planned to improve understanding of the Govisou mineralization.

  • Drilling at Bagoé permit, 70km from Perseus’s Sissingué Gold Mine , confirms gold mineralisation at the Antoinette, Véronique and Juliette prospects, with recent drill results including:

  • 12m @ 3.49 g/t Au from 0m and 17m @ 6.45 g/t Au from 32m (Antoinette)

  • 10m @ 4.19 g/t Au from 27m and 14m @ 3.21 g/t Au from 41m (Antoinette)

  • 6m @ 6.75 g/t Au from 27m, 11m @ 3.89 g/t Au from 44m and 10m @ 2.66 g/t Au from 68m (Antoinette)

  • 18m @ 8.42 g/t Au from 78m (Antoinette)

  • 20m @ 5.36 g/t Au from 1m (Antoinette)

  • 33m @ 2.94 g/t Au from 0m (Véronique)

  • 14m @ 6.29 g/t Au from 22m (Véronique)

  • 10m @ 6.16 g/t Au from 20m (Véronique)

  • 15m @ 3.30 g/t Au from 36m (Juliette)

  • 7m @ 7.78 g/t Au from 52m (Juliette)

Drill results from the Bagoé prospects will form the basis for a Definitive Feasibility Study (DFS) on a mining and trucking operation that will result in ore being transported to Sissingué for processing. The DFS is due to be completed in the June 2021 quarter.

  • Perseus is on track to deliver on its plan of producing more than 500,000oz gold pa from FY2022, with each of its Edikan, Sissingue and Yaoure gold mines in production and producing to plan.

Perseus Mining Limited ABN 27 106 808 986 Level 2, 437 Roberts Road Subiaco WA 6008 PO Box 1578 Subiaco WA 6008 Telephone: +61 8 6144 1700 Facsimile: +61 8 6144 1799 Email: [email protected] Website: www.perseusmining.com

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Perseus’s Managing Director & Chief Executive Officer, Mr Jeff Quartermaine said:

“For the last five years or so, Perseus has been very focussed on funding the development of new mines. In that time, we have spent nearly US$400 million developing two new mines, one at Sissingué and the other at Yaouré in Côte d’Ivoire. This has left little capital available to invest in the organic growth of our Company. With the completion of construction and the pouring of first gold at Yaouré in December 2020, we are now able to adequately fund exploration programmes aimed at extending the lives of all our existing mines and organically growing our Company.

The results published today illustrate the significant potential for the delineation of further Mineral Resources and Ore reserves in the vicinity of existing infrastructure at each of our mines. Our Yaouré tenements are showing excellent potential for further discoveries and the drilling results achieved at Bagoé demonstrate why Perseus acquired Exore Resources Limited last year and promise to provide mill feed to materially extend the life of our Sissingué operation.”

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PREAMBLE

Perseus Mining Limited (ASX/TSX: PRU) is pleased to provide an update on its recent exploration activities at its Bagoé and Yaouré properties, both located in Côte d’Ivoire. The results demonstrate the potential for the Company to organically grow its gold inventory through further drilling success.

Yaouré is Perseus’s third gold mine, commencing production in December 2020. Recent exploration has focused on the drilling of satellite prospects within five kilometres of the Yaouré mill with the potential to deliver shallow oxide ore during the early stages of the project. (Refer to Figure 1 ) Progress has also been made with the definition of drill targets from the 3D seismic survey completed in 2020, recently supplemented by the completion of an airborne gravity (FTGG) survey.

The Bagoé exploration licence, 60km south of Perseus’s Sissingué Gold Mine, (Refer to Figures 2 and 3 was acquired when Exore Resources Limited was acquired in September 2020 (ASX announcement 26[th] September 2020). Perseus’s pre-acquisition evaluation of Exore’s exploration work at Bagoé indicated potential for the economic exploitation of the Antoinette, Juliette and Véronique gold deposits by open pit mining and either processing in-situ or transporting ore to Sissingué for processing. Recent exploration drilling has focused on converting the previously defined Inferred Resources to Measured and Indicated Resources to support a DFS to confirm the technical and financial viability of the two development concepts.

YAOURÉ EXPLORATION DRILLING – GOVISOU AND ANGOVIA 2 PROSPECTS

Perseus has focused recent exploration activities at the Yaouré permits on the Angovia 2 and Govisou prospects, both within 5km of the Yaouré mill (Refer to Figure 1 ).

Particularly encouraging results have been returned from the Govisou prospect, 3km southwest of the Yaouré mill site, where 5,642 metres were drilled in 61 Reverse Circulation (“RC”) holes (with an additional 1,127 metres drilled in 14 holes during the December 2020 quarter). Mineralisation at Govisou occurs in pervasively altered and pyritized basaltic-andesitic volcanics intruded by a dioritic stock, with no clearly identifiable structural controls ( Figure 4 ). Better intercepts from this drilling programme are included in Table 1 below.

The geometry of the Govisou mineralisation remains uncertain at this stage, but current indications suggest a ‘pencil’-shaped plunging structure that remains open at depth ( Figure 5 ). Further drilling, including oriented diamond core holes, is planned to elucidate the structural and lithological controls on mineralisation at Govisou.

At Angovia 2, located 3 kilometres southeast of the Yaouré mill, results were received for Resource definition drilling completed in the December 2020 quarter aimed at defining shallow ore beneath the planned oxide pit. The results from this campaign suggest potential exists for a deepening of this pit beyond the currently planned depth. Better intercepts from this program are included in Table 1 below.

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A complete summary of the recent Yaouré drilling is included in Appendix A – Table 1.

Ongoing exploration programmes at Yaouré will focus on:

  • Follow up drilling at Govisou to elucidate the lithostructural controls on the mineralisation and to follow potential down plunge extensions to the high-grade pod defined in the latest drilling.

  • The commencement of drill testing of targets generated from the 3D seismic survey conducted in early 2020, with an initial focus on near-surface targets.

Table 1: Intercepts from Yaoure Mining Licence - Govisou and Angovia 2 Prospects

Govisou Angovia 2
YRC1457: 25m @ 3.33 g/t from 55m
YRC1458: 52m @ 3.02 g/t from 28m
YRC1459: 63m @ 2.35 g/t from 9m
YRC1460: 22m @ 2.58 g/t from 20m
YRC1558: 66m @ 1.47 g/t from 54m
YRC1559: 66m @ 2.13 g/t from 54m
YRC1560: 79m @ 1.25 g/t from 39m
YRC1562: 35m @ 1.33 g/t from 6m
YRC1564: 76m @ 1.86 g/t from 42m
YRC1565: 77m @ 2.47 g/t from 0m
YRC1571: 59m @ 2.05 g/t from 0m
YRC1572: 76m @ 2.40 g/t from 8m
YRC1573: 92m @ 2.60 g/t from 0m
YRC1574: 93m @ 2.74 g/t from 0m and 24m @
1.18 g/t from 98m
YRC1590: 86m @ 2.18 g/t from 30m
YRC1592: 64m @ 1.87 g/t from 50m
YRC1593: 51m @ 1.06 g/t from 69m
YRC1594: 39m @ 1.71 g/t from 78m
YRC1596: 65m @ 2.73 g/t from 24m and 35m @
3.49 g/t from 105m
YRC1597: 38m @ 1.23 g/t from 82m		 YRC1472: 23m @ 1.67 g/t from 37m
YRC1476: 31m @ 1.55 g/t from 8m
YRC1480: 11m @ 1.56 g/t from 94m
YRC1481: 43m @ 4.07 g/t from 76m
YRC1482: 15m @ 2.83 g/t from 73m
YRC1485: 12m @ 1.56 g/t from 46m
YRC1487: 43m @ 1.56 g/t from 45m
YRC1491: 9m @ 13.97 g/t from 4m
YRC1492: 43m @ 3.04 g/t from 5m
YRC1493: 14m @ 1.59 g/t from 13m
YRC1495: 13m @ 1.75 g/t from 23m
YRC1496: 7m @ 2.97 g/t from 33m
YRC1497: 14m @ 3.17 g/t from 13m
YRC1505: 8m @ 3.06 g/t from 12m
YRC1509: 15m @ 1.64 g/t from 9m
YRC1518: 16m @ 9.60 g/t from 0m
YRC1522: 13m @ 4.83 g/t from 41m
YRC1526: 25m @ 1.71 g/t from 9m
YRC1527: 16m @ 2.00 g/t from 36m
YRC1542: 2m @ 4.03 g/t from 63m
YRC1547: 10m @ 2.1 g/t from 40m and 7m @ 1.38
g/t from 58m
YRC1551: 22m @ 0.74 g/t from 7m
YRC1552: 12m @ 0.97 g/t from 19m
YRC1555: 21m @ 0.96 g/t from 2m and 10m @
1.15 g/t from 37m
YRC1556: 46m @ 0.71 g/t from 4m and 3m @ 1.56
g/t from 53m

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BAGOÉ EXPLORATION PERMIT

Resource definition drilling was undertaken at the Antoinette, Véronique and Juliette prospects on the Bagoé permit ( Figures 2 and 3 ). A total of 18,665 metres was drilled in 52 Air Core (“AC”), 252 RC and 6 diamond drilling (“DD”) holes, plus nine geotechnical and exploratory water bores. Almost all results have now been received for this drilling, generally confirming the tenor and width of previous drilling and suggesting possible extensions.

At Véronique, drilling defined strong mineralisation over a core zone of approximately 440 metres over widths of 3 to 9 metres. (Refer to Figures 6 and 7 ) Better intercepts are shown in Table 2 .

At Juliette, drilling confirmed strong mineralisation over a strike length of 250 metres with widths ranging from 4 to 22 metres ( Figures 8 and 9 ). The mineralisation remains open to the southwest and at depth. Better intercepts from the Juliette drilling are included in the second column of Table 2 .

Drilling at Antoinette Central was also successful in confirming strong mineralisation over a strike length of 875 metres with average widths of 5 to 44 metres. The mineralisation appears to remain open to both the northeast and southwest and at depth. (Refer to Figures 10 and 11 ) Better intercepts from the Antoinette drilling are included in the last column of Table 2 .

A complete summary of the recent Bagoé drilling is included in Appendix A - Table 2 .

Exploration will now focus on investigation of other prospective opportunities identified on the Bagoé tenement, including:

  • Strike and dip extensions to known deposits identified from the recent resource drilling.

  • The Antoinette-Juliette ‘gap’ to follow up previous encouraging intercepts in AC and RC drilling beneath transported cover.

  • Drilling to follow up encouraging drill intercepts between Antoinette and Antoinette South.

  • Drilling to follow up encouraging intercepts on potential repetitions of the Véronique deposit and at regional prospects such as Odette and Brigette.

  • Augering at early-stage regional prospects such as Ludivine.

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Table 2 Intercepts from Bagoé Exploration Permit - Véronique, Juliette and Antoinette Deposits**

Véronique BDAC001682: 5m @ 13.6 g/t from 43m BDAC001686: 15m @ 2.64 g/t from 10m BDAC001687: 33m @ 2.94 g/t from 0m BDAC001688: 14m @ 6.29 g/t from 22m BDAC001689: 7m @ 3.30 g/t from 23m BDAC001690: 8m @ 3.25 g/t from 37m BDAC001691: 5m @ 5.67 g/t from 18m BDAC001695: 9m @ 6.22 g/t from 25m BDRC0280: 6m @ 8.36 g/t from 56m BDRC0283: 5m @ 8.74 g/t from 53m BDRC0291: 5m @ 3.97 g/t from 53m BDRC0306: 2m @ 5.31 g/t from 21m BDRC0307: 9m @ 2.35 g/t from 18m BDRC0352: 10m @ 3.22 g/t from 27m BDRC0353: 6m @ 5.24 g/t from 12m BDRC0355: 10m @ 6.16 g/t from 20m BDRC0358: 9m @ 3.89 g/t from 17m BDRC0412: 2m @ 25.2 g/t from 17m BDRC0421: 3m @ 4.33 g/t from 22m BDRC0362: 15m @ 4.81 g/t from 3m BDRC0366: 3m @ 34.9 g/t from 37m BDRC0370: 3m @ 23.3 g/t from 21m BDRC0386: 8m @ 7.03 g/t from 13m BDRC0433: 6m @ 2.15 g/t from 14m BDRC0434: 3m @ 35.66 g/t from 10m BDRC0440: 6m @ 1.08 g/t from 16m BDRC0447: 10m @ 1.14 g/t from 7m BDRC0450: 4m @ 4.25 g/t from 30m BDRC0456: 20m @ 1.44 g/t from 64m BDRC0457: 2m @ 5.72 g/t from 67m

Juliette Antoinette BDRC0325: 15m @ 3.30 g/t from 36m BDAC01696: 11m @ 2.98 g/t from 0m BDRC0326: 12m @ 2.55 g/t from 55m BDAC01697: 11m @ 4.95 g/t from 6m BDRC0327: 10m @ 2.63 g/t from 38m BDAC01698: 20m @ 5.36 g/t from 1m BDRC0328: 9m @ 1.78 g/t from 52m BDAC01699: 14m @ 2.49 g/t from 4m BDRC0330: 8m @ 2.71 g/t from 37m BDAC01700: 12m @ 3.49 g/t from 0m BDRC0332: 7m @ 7.78 g/t from 52m and 17m @ 6.45 g/t from 32m BDRC0338: 6m @ 2.08 g/t from 64m BDRC0467: 10m @ 3.95 g/t from 7m and 8m @ 2.93 g/t from 30m BDRC0339: 22m @ 1.23 g/t from 40m BDRC0469: 10m @ 4.19 g/t from 27m BDRC0340: 16m @ 1.52 g/t from 48m and 14m @ 3.21 g/t from 41m BDRC0341: 9m @ 1.86 g/t from 6m and BDRC0469: 6m @ 6.75 g/t from 27m 8m @ 1.90 g/t from 34 and 11m @ 3.89 g/t from 44m and BDRC0342: 9m @ 2.39 g/t from 45m 10m @ 2.66 g/t from 68m BDRC0343: 13m @ 1.10 g/t from 26m BDRC0471: 44m @ 2.37 g/t from 12m BDRC0344: 13m @ 2.72 g/t from 26m BDRC0472: 6m @ 6.01 g/t from 17m BDRC0345: 13m @ 2.25 g/t from 43m BDRC0473: 14m @ 3.02 g/t from 0m BDRC0458: 5m @ 3.16 g/t from 36m BDRC0474: 32m @ 4.03 g/t from 33m BDRC0459: 10m @ 3.05 g/t from 50m BDRC0475: 8m @ 3.02 g/t from 49m BDRC0461: 16m @ 2.23 g/t from 41m BDRC0476: 11m @ 2.19 g/t from 34m BDRC0465: 18m @ 1.58 g/t from 39m BDRC0479: 21m @ 4.43 g/t from 29m BDRC0466: 19m @ 2.19 g/t from 59m BDRC0480: 10m @ 3.43 g/t from 65m and BDRC0480: 18m @ 8.42 g/t from 78m BDRC0481: 17m @ 2.74 g/t from 18m BDRC0482: 5m@ 2.08 g/t from 45m BDRC0483: 15m @ 2.5 g/t from 42m BDRC0484: 14m @ 3.35 g/t from 0m and 5m @ 2.00 g/t from 55m BDRC0485: 8m @ 3.42 g/t from 93m BDRC0486: 12m @ 2.16 g/t from 43m BDRC0488: 8m @ 2.36 g/t from 77m BDRC0489: 6m @ 2.22 g/t from 0m BDRC0490: 10m @ 3.27 g/t from 19m BDRC0491: 12m @ 2.83 g/t from 44m BDRC0492: 9m @ 4.09 g/t from 9m BDRC0494: 7m @ 2.53 g/t from 69m BDRC0496: 11m @ 4.12 g/t from 73m BDRC0497: 12m @ 8.32 g/t from 21m BDRC0498: 6m @ 2.47 g/t from 52m BDRC0505: 10m @ 7.13 g/t from 10m and 11m @ 3.22 g/t from 32m BDRC0507: 11m @ 2.45 g/t from 47m BDRC0513: 24m @ 3.33 g/t from 70m BDDD0015: 8.5m @ 3.35 g/t from 20m BDDD0016: 10m @ 3.54 g/t from 0m BDDD0017: 14m @ 4.23 g/t from 63m BDDD0020: 5m @ 28.56 g/t from 70m BDDD0021: 10m @ 9.14 g/t from 76m BDDD0021: 9m @ 17.88 g/t from 116m BDDD0022: 7m @ 6.92 g/t from 18m BDDD0022: 8m @ 2.53 g/t from 34m BDDD0022: 12m @ 6.01 from 74m

Notes:

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* Previously reported – ASX announcement of 20[th] January 2021.

** Significant intercepts calculated using a minimum grade of 0.3 g/t, a minimum length of 2m and maximum internal dilution of 2m.

This announcement has been approved for release by the Technical Committee of the Board of Directors of the Company.

To discuss any aspect of this announcement, please contact:

Managing Director: Jeff Quartermaine at telephone +61 8 6144 1700 or email [email protected]; Media Relations: Nathan Ryan at telephone +61 4 20 582 887 or email [email protected] (Melbourne)

Competent Person Statement:

All production targets for Edikan, Sissingué and Yaouré referred to in this report are underpinned by estimated Ore Reserves which have been prepared by competent persons in accordance with the requirements of the JORC Code. The information in this report that relates to Esuajah North Mineral Resources estimate was first reported by the Company in compliance with the JORC Code 2012 and NI43-101 in a market announcement entitled “Perseus Mining Updates Mineral Resources & Ore Reserves” released on 29 August 2018. The information in this report that relates to the Mineral Resource and Ore Reserve estimates for the Bokitsi South and AFG Gap deposits at the EGM was first reported by the Company in compliance with the JORC Code 2012 and NI43-101 in a market announcement released on 26 August 2020. The information in this report that relates to the Mineral Resource and Ore Reserve estimates for the other EGM deposits (Fetish and Esuajah South Underground) was first reported by the Company in compliance with the JORC Code 2012 and NI43-101 in a market announcement released on 20 February 2020 and was updated for depletion until 30 June 2020 in a market announcement released on 26 August 2020. The Company confirms that it is not aware of any new information or data that materially affect the information in those market releases and that all material assumptions underpinning those estimates and the production targets, or the forecast financial information derived therefrom, continue to apply and have not materially changed. The Company further confirms that material assumptions underpinning the estimates of Ore Reserves described in “Technical Report — Central Ashanti Gold Project, Ghana” dated 30 May 2011 continue to apply.

The information in this report that relates to Mineral Resources and Ore Reserves for Sissingué was first reported by the Company in compliance with the JORC Code 2012 and NI43-101 in a market announcement released on 29 October 2018 and includes an update for depletion as at 30 June 2020.The information in this report that relates to Mineral Resources and Ore Reserves for the Fimbiasso East and West deposits, previously Bélé East and West respectively, was first reported by the Company in compliance with the JORC Code 2012 and NI43-101 in a market announcement released on 26 August 2020. The Company confirms that material assumptions underpinning the estimates of Mineral Resources and Ore Reserves described in those market announcements. The Company confirms that it is not aware of any new information or data that materially affect the information in these market releases and that all material assumptions underpinning those estimates and the production targets, or the forecast financial information derived therefrom, continue to apply and have not materially changed. The Company further confirms that material assumptions underpinning the estimates of Ore Reserves described in “Technical Report — Sissingué Gold Project, Côte d’Ivoire” dated 29 May 2015 continue to apply. The information in this report in relation to Yaouré Mineral Resource and Ore Reserve estimates was first reported by the Company in compliance with the JORC Code 2012 and NI43-101 in a market announcement on 28 August 2019. The Company confirms that all material assumptions underpinning those estimates and the production targets, or the forecast financial information derived therefrom, in that market release continue to apply and have not materially changed. The Company further confirms that material assumptions underpinning the estimates of Ore Reserves described in “Technical Report — Yaouré Gold Project, Côte d’Ivoire” dated 18 December 2017 continue to apply.

The information in this report and the attachments that relate to exploration drilling results at the Yaouré and Bagoé Projects is based on, and fairly represents, information and supporting documentation prepared by Dr Douglas Jones, a Competent Person who is a Chartered Professional Geologist. Dr Jones is the Group General Manager Exploration of the Company. Dr Jones has sufficient experience, which is relevant to the style of mineralisation and type of deposit 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’”) and to qualify as a “Qualified Person” under National Instrument 43-101 – Standards of Disclosure for Mineral Projects (“NI 43-101”). Dr Jones consents to the inclusion in this report of the matters based on his information in the form and context in which it appears.

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Caution Regarding Forward Looking Information:

This report contains forward-looking information which is based on the assumptions, estimates, analysis and opinions of management made in light of its experience and its perception of trends, current conditions and expected developments, as well as other factors that management of the Company believes to be relevant and reasonable in the circumstances at the date that such statements are made, but which may prove to be incorrect. Assumptions have been made by the Company regarding, among other things: the price of gold, continuing commercial production at the Edikan Gold Mine and the Sissingué Gold Mine and achieving commercial production at the Yaouré Gold Mine without any major disruption due to the COVID-19 pandemic or otherwise, the receipt of required governmental approvals, the accuracy of capital and operating cost estimates, the ability of the Company to operate in a safe, efficient and effective manner and the ability of the Company to obtain financing as and when required and on reasonable terms. Readers are cautioned that the foregoing list is not exhaustive of all factors and assumptions which may have been used by the Company. Although management believes that the assumptions made by the Company and the expectations represented by such information are reasonable, there can be no assurance that the forward-looking information will prove to be accurate. Forward-looking information involves known and unknown risks, uncertainties, and other factors which may cause the actual results, performance or achievements of the Company to be materially different from any anticipated future results, performance or achievements expressed or implied by such forward-looking information. Such factors include, among others, the actual market price of gold, the actual results of current exploration, the actual results of future exploration, changes in project parameters as plans continue to be evaluated, as well as those factors disclosed in the Company's publicly filed documents. The Company believes that the assumptions and expectations reflected in the forward-looking information are reasonable. Assumptions have been made regarding, among other things, the Company’s ability to carry on its exploration and development activities, the timely receipt of required approvals, the price of gold, the ability of the Company to operate in a safe, efficient and effective manner and the ability of the Company to obtain financing as and when required and on reasonable terms. Readers should not place undue reliance on forward-looking information. Perseus does not undertake to update any forward-looking information, except in accordance with applicable securities laws.

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Figure 1: Yaouré Gold Project – Exploration Targets

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Figure 2: Sissingué Gold Mine and Bagoé Permit and Prospects

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Figure 3: Bagoé Permit Deposits and Prospects

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Figure 4: Govisou prospect - Plan View of Gold Intercepts

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Figure 5: Govisou prospect: SE/NW Vertical Section - Looking SW

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Figure 6: Véronique Drilling Results - Plan View of Gold Intercepts

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Figure 7: Véronique Vertical Section – looking NW

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Figure 8: Juliette Drilling Results - Plan View of Gold Intercepts

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Figure 9: Juliette Vertical Section - Looking NE

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Figure 10: Antoinette Drilling Results - Plan View of Gold Intercepts

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Figure 11: Antoinette Vertical Section – Looking NE

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APPENDIX A – DETAILED DRILL RESULTS

Table 1: Yaouré drill holes and significant intercepts

Hole ID East North RL Drill
T		 Azimuth Dip Depth No of
l		 From To Width Grade
(mE) (mN) (mRL) ype (°) (°) (m) sampes (m) (m) (m) (g/t)
GOVISOU
YDD0542 219416.62 777512.405 244.63 DD 225 -50 275.7 22 159 177 18 0.59
YDD0543 219327.297 777579.849 246.69 DD 130 -50 285.3 21 152 168 16 0.52
YRC1435 219363.6253 777542.3088 240.207 RC 325 -55 87 NSI
YRC1436 219396.667 777509.959 245.199 RC 325 -55 80 NSI
YRC1437 219418.7956 777486.058 247.106 RC 325 -55 80 NSI
YRC1438 219449.8179 777458.0204 247.995 RC 325 -55 80 NSI
YRC1451 219152.1265 777417.8484 250.613 RC 135 -55 80 NSI
YRC1452 219176.2503 777392.0717 255.17 RC 135 -55 80 NSI
YRC1453 219203.2689 777362.591 256.496 RC 135 -55 80 NSI
YRC1454 219227.3354 777337.4479 257.249 RC 135 -55 80 2 0 5 5 1.36
YRC1455 219290.9681 777389.8992 253.868 RC 135 -55 80 9 42 58 16 0.54
YRC1456 219265.0363 777415.0898 253.258 RC 135 -55 80 17 34 67 33 0.5
YRC1457 219272.3824 777464.7578 250.886 RC 135 -55 80 13 55 80 25 3.33
YRC1458 219299.6398 777438.3718 251.208 RC 135 -55 80 32 28 80 52 3.02
YRC1459 219327.949 777408.3488 252.461 RC 135 -55 80 36 9 72 63 2.35
YRC1460 219345.3809 777450.9415 248.511 RC 135 -55 80 7 2 16 14 0.83
YRC1460 219345.3809 777450.9415 248.511 RC 135 -55 80 11 20 42 22 2.58
YRC1558 219284.756 777476.117 249.896 RC 135 -55 120 9 26 38 12 0.39
YRC1558 219284.756 777476.117 249.896 RC 135 -55 120 52 54 120 66 1.47
YRC1559 219300.127 777465.712 249.452 RC 135 -55 120 12 10 29 19 0.3
YRC1559 219300.127 777465.712 249.452 RC 135 -55 120 52 54 120 66 2.13
YRC1560 219313.855 777451.746 249.75 RC 135 -55 120 55 39 118 79 1.25
YRC1561 219327.405 777438.066 250.94 RC 135 -55 100 29 25 79 54 0.89
YRC1561 219327.405 777438.066 250.94 RC 135 -55 100 3 84 89 5 1.15
YRC1562 219341.787 777423.787 251.534 RC 135 -55 80 19 6 41 35 1.33
YRC1563 219356.245 777409.392 251.746 RC 135 -55 60 NSI
YRC1564 219284.981 777452.653 250.822 RC 135 -55 120 56 42 118 76 1.86
YRC1565 219312.667 777424.745 252.16 RC 135 -55 120 44 0 77 77 2.47

20

==> picture [114 x 35] intentionally omitted <==

YRC1565 219312.667 777424.745 252.16 RC 135 -55 120 18 83 112 29 0.37
YRC1566 219341.128 777396.253 253.287 RC 135 -55 80 9 6 18 12 0.99
YRC1566 219341.128 777396.253 253.287 RC 135 -55 80 9 22 38 16 0.97
YRC1567 219355.412 777382.12 253.185 RC 135 -55 60 NSI
YRC1568 219368.856 777368.383 254.114 RC 135 -55 40 NSI
YRC1569 219325.839 777383.01 254.54 RC 135 -55 80 13 7 28 21 0.48
YRC1569 219325.839 777383.01 254.54 RC 135 -55 80 17 32 57 25 0.26
YRC1570 219312.64 777396.56 253.875 RC 135 -55 100 21 6 44 38 0.64
YRC1571 219298.892 777410.169 252.812 RC 135 -55 132 31 0 59 59 2.05
YRC1571 219298.892 777410.169 252.812 RC 135 -55 132 10 68 83 15 0.29
YRC1571 219298.892 777410.169 252.812 RC 135 -55 132 7 106 115 9 0.81
YRC1572 219285.028 777424.592 252.68 RC 135 -55 120 43 8 84 76 2.4
YRC1573 219270.671 777438.473 252.28 RC 135 -55 120 50 0 92 92 2.6
YRC1574 219258.276 777450.875 251.718 RC 135 -55 122 57 0 93 93 2.74
YRC1574 219258.276 777450.875 251.718 RC 135 -55 122 16 98 122 24 1.18
YRC1575 219248.331 777432.481 252.716 RC 135 -55 124 25 40 85 45 0.87
YRC1576 219274.955 777406.029 253.773 RC 135 -55 120 7 38 52 14 0.39
YRC1577 219302.852 777378.023 254.674 RC 135 -55 90 NSI
YRC1578 219316.642 777364.388 254.99 RC 135 -55 70 7 14 28 14 0.45
YRC1579 219275.444 777376.845 254.674 RC 135 -55 50 NSI
YRC1580 219261.253 777390.634 254.535 RC 135 -55 75 NSI
YRC1581 219247.789 777403.813 254.32 RC 135 -55 100 18 74 96 22 0.58
YRC1582 219234.089 777418.915 253.636 RC 135 -55 100 20 72 100 28 0.87
YRC1583 219220.245 777432.732 252.1 RC 135 -55 100 NSI
YRC1584 219207.273 777445.755 250.874 RC 135 -55 100 NSI
YRC1585 219205.092 777419.274 253.66 RC 135 -55 80 NSI
YRC1586 219219.033 777405.344 254.582 RC 135 -55 80 NSI
YRC1587 219231.838 777392.256 254.983 RC 135 -55 80 NSI
YRC1588 219247.787 777376.68 255.372 RC 135 -55 60 NSI
YRC1589 219221.476 777459.595 247.863 RC 135 -55 110 NSI
YRC1590 219243.957 777464.856 246.983 RC 135 -55 162 3 18 24 6 1.36
YRC1590 219243.957 777464.856 246.983 RC 135 -55 162 56 30 116 86 2.18
YRC1591 219246.829 777490.896 245.388 RC 135 -55 168 3 54 59 5 0.84

21

==> picture [114 x 35] intentionally omitted <==

YRC1591 219246.829 777490.896 245.388 RC 135 -55 168 29 73 124 51 0.91
YRC1592 219261.02 777504.557 244.933 RC 135 -55 114 39 50 114 64 1.87
YRC1593 219279.36 777514.777 244.633 RC 135 -55 120 12 39 63 24 0.53
YRC1593 219279.36 777514.777 244.633 RC 135 -55 120 43 69 120 51 1.06
YRC1594 219272.967 777492.581 245.881 RC 135 -55 117 15 49 75 26 0.26
YRC1594 219272.967 777492.581 245.881 RC 135 -55 117 28 78 117 39 1.71
YRC1595 219231.761 777478.526 245.513 RC 135 -55 164 26 90 127 37 0.63
YRC1596 219258.095 777479.35 246.395 RC 135 -55 170 34 24 89 65 2.73
YRC1596 219258.095 777479.35 246.395 RC 135 -55 170 6 93 100 7 1.2
YRC1596 219258.095 777479.35 246.395 RC 135 -55 170 26 105 140 35 3.49
YRC1597 219293.009 777500.808 245.499 RC 135 -55 120 9 61 79 18 0.42
YRC1597 219293.009 777500.808 245.499 RC 135 -55 120 26 82 120 38 1.23
YRC1598 219324.233 777469.747 247.863 RC 135 -55 128 1 4 6 2 4.86
YRC1598 219324.233 777469.747 247.863 RC 135 -55 128 17 28 62 34 0.5
YRC1598 219324.233 777469.747 247.863 RC 135 -55 128 8 66 80 14 0.46
YRC1599 219353.381 777441.172 249.688 RC 135 -55 60 7 9 22 13 0.86
YRC1600 219393.991 777428.249 249.608 RC 135 -55 40 1 0 4 4 4.17
YRC1601 219381.034 777441.569 249.281 RC 135 -55 50 NSI
YRC1602 219366.412 777455.905 248.892 RC 135 -55 70 NSI
YRC1603 219352.333 777470.395 247.718 RC 135 -55 90 9 24 42 18 0.31
YRC1604 219339.347 777483.175 245.837 RC 135 -55 90 16 47 72 25 0.77
YRC1605 219325.498 777496.874 244.52 RC 135 -55 90 1 4 6 2 2.48
YRC1605 219325.498 777496.874 244.52 RC 135 -55 90 25 53 87 34 0.44
YRC1606 219353.789 777524.896 240.074 RC 135 -55 50 NSI
YRC1607 219339.144 777511.29 241.339 RC 135 -55 66 9 36 47 11 0.41
YRC1608 219312.418 777510.371 244.049 RC 135 -55 90 3 2 8 6 2.08
YRC1608 219312.418 777510.371 244.049 RC 135 -55 90 16 64 86 22 0.41
YRC1609 219369.391 777509.61 244.471 RC 135 -55 60 11 14 36 22 0.66
YRC1610 219353.967 777496.335 245.111 RC 135 -55 70 NSI
YRC1611 219393.828 777456.424 249.299 RC 135 -55 50 NSI
YRC1612 219408.392 777470.645 249.098 RC 135 -55 40 NSI
YRC1613 219394.093 777485.101 247.972 RC 135 -55 60 NSI
YRC1614A 219384.083 777495.263 246.599 RC 135 -55 18 NSI

22

==> picture [114 x 35] intentionally omitted <==

YRC1614B 219388.083 777495.263 246.599 RC 135 -55 60 NSI
YRC1615 219379.237 777471.869 248.344 RC 135 -55 60 NSI
YRC1616 219366.64 777484.422 246.797 RC 135 -55 70 NSI
ANGOVIA 2
YDD0550 221771.103 776350.362 298.074 DD 290 -90 123.8 17 14 30 16 1.22
YDD0550 221771.103 776350.362 298.074 DD 290 -90 123.8 2 35 37 2 2.54
YDD0550 221771.103 776350.362 298.074 DD 290 -90 123.8 2 81 83 2 2.27
YDD0551 221799.726 776344.964 299.381 DD 270 -50 153.5 17 61 76 15 0.29
YDD0551 221799.726 776344.964 299.381 DD 270 -50 153.5 15 84 98 14 0.81
YDD0551 221799.726 776344.964 299.381 DD 270 -50 153.5 23 101 122 21 0.73
YDD0552 221840.325 776345.081 299.429 DD 270 -50 153.8 15 25 39 14 1.02
YDD0552 221840.325 776345.081 299.429 DD 270 -50 153.8 8 59 66 7 1.05
YDD0552 221840.325 776345.081 299.429 DD 270 -50 153.8 3 120 123 3 1.61
YDD0552 221840.325 776345.081 299.429 DD 270 -50 153.8 3 142.15 145 2.85 1.45
YDD0553 221744.982 776400.188 304.674 DD 180 -55 150.7 11 37 47 10 1.03
YDD0553 221744.982 776400.188 304.674 DD 180 -55 150.7 32 94 124 30 1.6
YDD0553 221744.982 776400.188 304.674 DD 180 -55 150.7 19 131 147.1 16.1 0.84
YDD0554 221743.918 776335.577 288.959 DD 270 -90 112.1 6 9.7 18 8.3 0.66
YDD0554 221743.918 776335.577 288.959 DD 270 -90 112.1 6 32 37 5 1.83
YDD0554 221743.918 776335.577 288.959 DD 270 -90 112.1 9 63 72 9 1
YDD0554 221743.918 776335.577 288.959 DD 270 -90 112.1 26 88.6 111 22.4 0.99
YDD0555 221771.844 776400.126 314.788 DD 180 -55 159.9 6 0 9 9 0.86
YDD0555 221771.844 776400.126 314.788 DD 180 -55 159.9 5 45 50 5 4.86
YDD0555 221771.844 776400.126 314.788 DD 180 -55 159.9 38 55 91 36 0.69
YDD0555 221771.844 776400.126 314.788 DD 180 -55 159.9 5 108 113 5 0.88
YDD0555 221771.844 776400.126 314.788 DD 180 -55 159.9 9 116 124.3 8.3 6.18
YDD0555 221771.844 776400.126 314.788 DD 180 -55 159.9 22 141.3 159.9 18.6 2.95
YRC1461 221607.1511 776242.958 261.429 RC 0 -55 48 NSI
YRC1462 221607.1336 776264.7614 262.904 RC 0 -55 54 7 46 53 7 0.75
YRC1463 221631.7837 776240.7776 262.706 RC 0 -55 54 NSI
YRC1464 221631.9039 776264.232 264.267 RC 0 -55 54 NSI
YRC1465 221631.9149 776287.5046 265.927 RC 0 -55 60 28 19 47 28 0.81
YRC1465 221631.9149 776287.5046 265.927 RC 0 -55 60 5 50 55 5 0.98

23

==> picture [114 x 35] intentionally omitted <==

YRC1466 221656.8829 776238.7412 265.377 RC 0 -55 54 NSI
YRC1467 221656.8411 776262.7742 266.282 RC 0 -55 54 2 0 2 2 3.38
YRC1467 221656.8411 776262.7742 266.282 RC 0 -55 54 2 24 26 2 3.4
YRC1468 221656.8705 776286.852 267.626 RC 0 -55 60 12 47 59 12 0.92
YRC1469 221656.8434 776306.5074 270.474 RC 0 -55 60 20 33 53 20 0.61
YRC1470 221681.9018 776235.8473 269.587 RC 0 -55 48 6 41 47 6 1.01
YRC1471 221681.8449 776259.4706 271.263 RC 0 -55 60 22 29 51 22 0.71
YRC1471 221681.8449 776259.4706 271.263 RC 0 -55 60 6 54 60 6 0.94
YRC1472 221681.8461 776282.7469 273.126 RC 0 -55 66 23 37 60 23 1.7
YRC1473 221681.775 776307.1105 275.125 RC 0 -55 66 16 0 16 16 0.75
YRC1473 221681.775 776307.1105 275.125 RC 0 -55 66 8 55 63 8 0.86
YRC1474 221707.1063 776232.8159 273.553 RC 0 -55 66 NSI
YRC1475 221706.7705 776254.6724 276.435 RC 0 -55 96 10 20 30 10 0.51
YRC1476 221706.9648 776279.8104 277.955 RC 0 -55 96 30 8 39 31 1.55
YRC1476 221706.9648 776279.8104 277.955 RC 0 -55 96 24 72 96 24 1.09
YRC1477 221706.9832 776303.5619 278.675 RC 0 -55 96 14 0 15 15 0.79
YRC1477 221706.9832 776303.5619 278.675 RC 0 -55 96 5 65 70 5 1.4
YRC1477 221706.9832 776303.5619 278.675 RC 0 -55 96 15 77 92 15 0.58
YRC1478 221756.9577 776232.8566 278.177 RC 0 -55 66 19 46 65 19 0.66
YRC1479 221756.9331 776251.6317 280.9 RC 0 -55 117 40 6 46 40 1.19
YRC1479 221756.9331 776251.6317 280.9 RC 0 -55 117 17 49 66 17 0.69
YRC1480 221757.1314 776275.178 283.699 RC 0 -55 114 17 8 25 17 1.08
YRC1480 221757.1314 776275.178 283.699 RC 0 -55 114 6 28 34 6 0.9
YRC1480 221757.1314 776275.178 283.699 RC 0 -55 114 11 94 105 11 1.56
YRC1481 221757.4815 776298.7511 289.17 RC 0 -55 120 14 9 23 14 1.39
YRC1481 221757.4815 776298.7511 289.17 RC 0 -55 120 28 43 71 28 2.97
YRC1481 221757.4815 776298.7511 289.17 RC 0 -55 120 43 76 119 43 4.07
YRC1482 221756.8813 776320.0965 291.677 RC 0 -55 102 15 0 15 15 0.87
YRC1482 221756.8813 776320.0965 291.677 RC 0 -55 102 12 18 30 12 1.25
YRC1482 221756.8813 776320.0965 291.677 RC 0 -55 102 10 53 63 10 0.69
YRC1482 221756.8813 776320.0965 291.677 RC 0 -55 102 15 73 88 15 2.83
YRC1483 221756.9199 776340.9654 294.422 RC 0 -55 90 7 9 16 7 0.68
YRC1483 221756.9199 776340.9654 294.422 RC 0 -55 90 6 19 25 6 6.03

24

==> picture [114 x 35] intentionally omitted <==

YRC1483 221756.9199 776340.9654 294.422 RC 0 -55 90 27 46 73 27 0.72
YRC1483 221756.9199 776340.9654 294.422 RC 0 -55 90 2 78 80 2 2.97
YRC1484 221757.2762 776363.1751 299.66 RC 0 -55 84 9 0 9 9 0.91
YRC1484 221757.2762 776363.1751 299.66 RC 0 -55 84 9 17 26 9 1.2
YRC1484 221757.2762 776363.1751 299.66 RC 0 -55 84 22 57 79 22 1.1
YRC1485 221756.0746 776385.4036 302.503 RC 0 -55 78 14 15 29 14 0.63
YRC1485 221756.0746 776385.4036 302.503 RC 0 -55 78 12 46 58 12 1.56
YRC1486 221807.1792 776254.621 280.91 RC 0 -55 84 2 22 24 2 3.04
YRC1486 221807.1792 776254.621 280.91 RC 0 -55 84 11 38 49 11 0.52
YRC1486 221807.1792 776254.621 280.91 RC 0 -55 84 15 56 71 15 0.4
YRC1487 221806.9474 776274.6504 284.489 RC 0 -55 90 16 14 30 16 1.54
YRC1487 221806.9474 776274.6504 284.489 RC 0 -55 90 43 45 88 43 1.56
YRC1488 221807.3079 776296.7698 289.504 RC 0 -55 96 9 13 22 9 0.51
YRC1488 221807.3079 776296.7698 289.504 RC 0 -55 96 21 35 56 21 1.35
YRC1488 221807.3079 776296.7698 289.504 RC 0 -55 96 8 60 68 8 2.08
YRC1489 221806.9965 776319.9907 293.093 RC 0 -55 90 27 9 36 27 1.16
YRC1489 221806.9965 776319.9907 293.093 RC 0 -55 90 12 40 52 12 0.46
YRC1490 221807.0403 776343.9134 298.826 RC 0 -55 84 19 31 50 19 0.95
YRC1491 221857.1206 776227.1412 281.238 RC 0 -55 60 9 4 13 9 13.97
YRC1491 221857.1206 776227.1412 281.238 RC 0 -55 60 11 31 42 11 2.77
YRC1491 221857.1206 776227.1412 281.238 RC 0 -55 60 6 54 60 6 1.1
YRC1492 221856.617 776249.7919 284.662 RC 0 -55 66 43 5 48 43 3.04
YRC1493 221856.491 776271.049 288.385 RC 0 -55 72 14 13 27 14 1.59
YRC1493 221856.491 776271.049 288.385 RC 0 -55 72 12 42 54 12 0.53
YRC1493 221856.491 776271.049 288.385 RC 0 -55 72 2 64 66 2 2.21
YRC1494 221856.4254 776293.9372 292.664 RC 0 -55 78 8 5 13 8 0.51
YRC1495 221856.6215 776316.7504 296.742 RC 0 -55 78 5 14 20 6 0.72
YRC1495 221856.6215 776316.7504 296.742 RC 0 -55 78 13 23 36 13 1.75
YRC1496 221856.8536 776339.3237 299.288 RC 0 -55 84 7 33 40 7 2.97
YRC1497 221856.9602 776362.4843 301.971 RC 0 -55 90 11 16 27 11 3.13
YRC1497 221856.9602 776362.4843 301.971 RC 0 -55 90 32 48 80 32 1
YRC1498 221906.6913 776205.3218 277.214 RC 0 -55 61 13 0 13 13 0.55
YRC1499 221906.3078 776226.398 280.928 RC 0 -55 66 NSI

25

==> picture [114 x 35] intentionally omitted <==

YRC1500 221906.5218 776247.606 284.957 RC 0 -55 68 NSI
YRC1501 221906.3374 776272.8274 289.232 RC 0 -55 72 7 0 8 8 0.59
YRC1501 221906.3374 776272.8274 289.232 RC 0 -55 72 13 22 35 13 0.75
YRC1501 221906.3374 776272.8274 289.232 RC 0 -55 72 8 43 51 8 1.02
YRC1502 221906.761 776292.8851 292.766 RC 0 -55 66 24 0 25 25 0.74
YRC1503 221906.5997 776317.2547 295.698 RC 0 -55 66 10 23 33 10 0.56
YRC1504 221906.5769 776339.8054 298.399 RC 0 -55 72 12 0 12 12 0.6
YRC1504 221906.5769 776339.8054 298.399 RC 0 -55 72 7 35 42 7 0.87
YRC1504 221906.5769 776339.8054 298.399 RC 0 -55 72 16 56 72 16 0.6
YRC1505 221953.8773 776225.2965 282.444 RC 0 -55 54 8 12 20 8 3.06
YRC1506 221954.5117 776248.5914 284.925 RC 0 -55 56 NSI
YRC1507 221952.077 776263.1486 286.575 RC 0 -55 54 11 5 16 11 0.85
YRC1507 221952.077 776263.1486 286.575 RC 0 -55 54 19 35 54 19 0.95
YRC1508 221954.9523 776324.5707 303.547 RC 0 -90 36 NSI
YRC1509 221956.1425 776290.3425 297.351 RC 0 -55 60 15 9 24 15 1.64
YRC1510 222004.9612 776497.347 313.581 RC 0 -55 42 12 0 13 13 0.39
YRC1511 222005.7152 776474.263 312.657 RC 0 -55 42 10 0 10 10 0.55
YRC1511 222005.7152 776474.263 312.657 RC 0 -55 42 6 13 19 6 1.77
YRC1512 222006.1056 776449.4521 312.831 RC 0 -55 42 NSI
YRC1513 222007.0199 776424.6594 315.005 RC 0 -55 42 24 0 25 25 0.36
YRC1514 222010.5504 776397.2172 320.42 RC 0 -55 48 14 0 16 16 0.81
YRC1514 222010.5504 776397.2172 320.42 RC 0 -55 48 26 19 45 26 0.55
YRC1515 222007.5928 776365.3533 326.562 RC 0 -55 60 11 0 11 11 0.73
YRC1515 222007.5928 776365.3533 326.562 RC 0 -55 60 27 32 59 27 0.96
YRC1516 221957.4187 776425.4401 320.457 RC 0 -55 48 22 1 23 22 0.55
YRC1516 221957.4187 776425.4401 320.457 RC 0 -55 48 13 27 40 13 0.38
YRC1517 221956.1181 776398.288 323.359 RC 0 -55 54 10 0 11 11 0.61
YRC1517 221956.1181 776398.288 323.359 RC 0 -55 54 12 14 26 12 0.51
YRC1517 221956.1181 776398.288 323.359 RC 0 -55 54 10 32 42 10 1.3
YRC1518 221956.4004 776375.8531 321.676 RC 0 -55 54 16 0 16 16 9.6
YRC1519 221957.2826 776375.7838 321.682 RC 0 -90 54 22 0 22 22 0.54
YRC1519 221957.2826 776375.7838 321.682 RC 0 -90 54 11 41 52 11 0.55
YRC1520 222010.9771 776261.7566 307.916 RC 160 -90 36 NSI

26

==> picture [114 x 35] intentionally omitted <==

YRC1521 222009.2612 776286.7697 313.278 RC 70 -90 42 NSI
YRC1522 222003.1669 776307.9137 318.202 RC 160 -90 54 13 41 54 13 4.83
YRC1523 222012.6868 776337.8917 330.555 RC 0 -90 60 15 0 18 18 0.82
YRC1524 222012.665 776335.5975 330.644 RC 25 -90 60 23 13 37 24 0.54
YRC1525 221907.0498 776430.1551 329.136 RC 115 -90 60 11 0 11 11 0.81
YRC1525 221907.0498 776430.1551 329.136 RC 115 -90 60 12 26 40 14 0.31
YRC1525 221907.0498 776430.1551 329.136 RC 115 -90 60 5 48 53 5 1.57
YRC1526 221907.6979 776405.3138 327.907 RC 180 -90 72 5 0 5 5 0.96
YRC1526 221907.6979 776405.3138 327.907 RC 180 -90 72 25 9 34 25 1.71
YRC1526 221907.6979 776405.3138 327.907 RC 180 -90 72 11 55 66 11 0.63
YRC1527 221907.7891 776404.6369 327.795 RC 350 -90 78 5 0 5 5 1.67
YRC1527 221907.7891 776404.6369 327.795 RC 350 -90 78 9 8 17 9 0.77
YRC1527 221907.7891 776404.6369 327.795 RC 350 -90 78 16 36 52 16 2
YRC1528 221857.8413 776436.5312 336.878 RC 180 -60 78 9 0 9 9 0.69
YRC1528 221857.8413 776436.5312 336.878 RC 180 -60 78 11 21 32 11 0.85
YRC1528 221857.8413 776436.5312 336.878 RC 180 -60 78 6 36 42 6 2.14
YRC1528 221857.8413 776436.5312 336.878 RC 180 -60 78 23 51 74 23 0.85
YRC1529 221857.0284 776435.418 337.123 RC 110 -90 66 10 0 10 10 1.18
YRC1529 221857.0284 776435.418 337.123 RC 110 -90 66 37 13 50 37 0.71
YRC1530 221757.1487 776430.7517 317.506 RC 165 -90 66 NSI
YRC1531 221796.4245 776402.915 316.977 RC 0 0 78 7 10 17 7 0.62
YRC1531 221796.4245 776402.915 316.977 RC 0 0 78 7 37 44 7 0.72
YRC1532 221807.2139 776380.8209 312.517 RC 105 -90 60 25 24 49 25 0.62
YRC1533 221606.1028 776297.3209 277.206 RC 200 -90 54 33 0 33 33 0.58
YRC1533 221606.1028 776297.3209 277.206 RC 200 -90 54 7 47 54 7 0.92
YRC1534 221606.8888 776320.4083 287.052 RC 200 -90 66 33 31 64 33 1.14
YRC1535 221606.6605 776345.9871 291.539 RC 350 -90 72 9 55 64 9 0.49
YRC1536 221607.0622 776371.3096 296.64 RC 10 -90 83 5 3 8 5 0.92
YRC1536 221607.0622 776371.3096 296.64 RC 10 -90 83 22 43 65 22 0.63
YRC1537 221607.2135 776396.1952 301.399 RC 35 -90 86 31 31 62 31 0.85
YRC1537 221607.2135 776396.1952 301.399 RC 35 -90 86 2 66 68 2 2.91
YRC1538 221632.0716 776424.0832 309.424 RC 255 -90 60 2 46 48 2 6
YRC1539 221632.236 776449.0919 313.188 RC 135 -90 54 19 11 30 19 0.51

27

==> picture [114 x 35] intentionally omitted <==

YRC1540 221632.4742 776400.1051 304.952 RC 345 -90 68 NSI
YRC1541 221657.0578 776448.0998 317.315 RC 345 -90 60 NSI
YRC1542 221657.0098 776423.5328 313.653 RC 270 -90 66 10 0 10 10 0.46
YRC1542 221657.0098 776423.5328 313.653 RC 270 -90 66 2 63 65 2 4.03
YRC1543 221657.1205 776398.5721 310.197 RC 320 -90 72 4 64 68 4 1.08
YRC1544 221657.1311 776378.452 304.907 RC 170 -90 72 13 45 58 13 0.49
YRC1545 221633.7511 776371.8496 299.172 RC 220 -90 72 23 31 54 23 0.31
YRC1546 221682.2286 776391.1449 308.378 RC 10 -90 72 NSI
YRC1547 221681.7577 776415.7323 315.762 RC 215 -90 72 10 40 50 10 2.1
YRC1547 221681.7577 776415.7323 315.762 RC 215 -90 72 7 58 65 7 1.38
YRC1548 221707.031 776416.1648 315.663 RC 175 -90 84 NSI
YRC1549 221707.1232 776368.2551 298.708 RC 110 -90 66 14 0 17 17 0.43
YRC1549 221707.1232 776368.2551 298.708 RC 110 -90 66 10 34 44 10 0.95
YRC1549 221707.1232 776368.2551 298.708 RC 110 -90 66 7 59 66 7 0.84
YRC1550 221682.141 776362.0592 296.111 RC 305 -90 72 NSI
YRC1551 221655.6574 776350.3268 290.987 RC 320 -90 72 22 7 29 22 0.74
YRC1552 221682.7831 776346.2685 289.25 RC 200 -90 60 12 19 31 12 0.97
YRC1553 221633.6785 776350.435 294.194 RC 170 -90 72 NSI
YRC1554 221705.2743 776390.008 303.24 RC 130 -90 72 23 33 56 23 0.74
YRC1555 221706.9716 776332.3203 284.054 RC 0 -55 72 24 2 26 24 0.88
YRC1555 221706.9716 776332.3203 284.054 RC 0 -55 72 10 37 47 10 1.15
YRC1555 221706.9716 776332.3203 284.054 RC 0 -55 72 16 56 72 16 0.63
YRC1556 221633.2528 776319.6245 275.652 RC 245 -90 60 46 4 50 46 0.71
YRC1556 221633.2528 776319.6245 275.652 RC 245 -90 60 3 53 56 3 1.56
YRC1557 221948.8438 776342.3916 304.917 RC 45 -90 54 NSI

28

==> picture [114 x 35] intentionally omitted <==

Table 2: Bagoé drill holes and significant intercepts

Hole ID East North RL Drill Type Azimuth Dip Depth No of
l		 From To Width Grade
(mE) (mN) (mRL) (°) (°) (m) sampes (m) (m) (m) (g/t)
ANTOINETTE
BDAC001696 812913.8631 1099734.548 405.13 AC 315 -60 36 11 0 11 11 2.98
BDAC001697 812887.5282 1099693.364 405.356 AC 315 -60 36 11 6 17 11 4.95
BDAC001697 812887.5282 1099693.364 405.356 AC 315 -60 36 2 18 20 2 3.48
BDAC001698 812854.3321 1099658.443 405.531 AC 315 -60 36 20 1 21 20 5.36
BDAC001699 812817.7286 1099622.596 409.138 AC 315 -60 36 2 0 2 2 10.78
BDAC001699 812817.7286 1099622.596 409.138 AC 315 -60 36 14 4 18 14 2.49
BDAC001700 812807.1961 1099596.726 406.035 AC 315 -60 48 12 0 12 12 3.49
BDAC001700 812807.1961 1099596.726 406.035 AC 315 -60 48 17 15 32 17 6.45
BDAC001701 812714.086 1099547.406 404.01 AC 315 -60 24 NSI
BDAC001702 812619.3287 1099466.962 400.656 AC 315 -60 24 2 6 8 2 2.82
BDAC001703 812634.2824 1099452.352 400.672 AC 315 -60 30 7 0 7 7 1.11
BDAC001704 812601.497 1099451.296 399.984 AC 315 -60 24 2 10 12 2 3.28
BDAC001705 812581.3017 1099433.505 399.483 AC 315 -60 24 NSI
BDAC001706 812561.3759 1099418.832 398.886 AC 315 -60 36 NSI
BDAC001707 812546.3991 1099399.117 398.3 AC 315 -60 24 NSI
BDAC001708 812511.7816 1099360.765 397.127 AC 315 -60 24 NSI
BDAC001709 812491.578 1099348.901 396.697 AC 315 -60 30 6 1 7 6 0.7
BDAC001710 812472.0347 1099330.893 396.244 AC 315 -60 24 NSI
BDAC001711 812470.9037 1099300.07 395.631 AC 315 -60 48 5 16 21 5 0.94
BDAC001711 812470.9037 1099300.07 395.631 AC 315 -60 48 6 29 35 6 1.53
BDAC001712 812467.6072 1099263.358 395.039 AC 315 -60 42 9 22 31 9 0.68
BDAC001713 812454.0097 1099276.652 395.217 AC 315 -60 24 4 8 12 4 2.7
BDDD0013 812792.1028 1099469.456 404.227 DD 315 -50 100 NSI
BDDD0014 812739.2387 1099664.476 406.306 DD 135 -50 105 NSI
BDDD0015 812733.9401 1099527.31 404.202 DD 315 -50 75 15 20 28.5 8.5 3.35
BDDD0015 812733.9401 1099527.31 404.202 DD 315 -50 75 7 45.5 49.5 4 4.98
BDDD0016 812802.9513 1099600.495 405.882 DD 135 -50 85 10 0 10 10 3.54
BDDD0016 812802.9513 1099600.495 405.882 DD 135 -50 85 4 66 70 4 1.11
BDDD0017 812715.918 1099475.43 402.867 DD 315 -60 116 14 63 77 14 4.23

29

==> picture [114 x 35] intentionally omitted <==

BDDD0017 812715.918 1099475.43 402.867 DD 315 -60 116 11 85 96 11 1.69
BDDD0018 812811 1099613 387 DD 315 -60 19.4 NSI
BDDD0019 812811.5 1099613 387 DD 315 -60 13.6 NSI
BDDD0020 812813.7879 1099570.603 406.029 DD 315 -60 85 20 5.5 25.7 20.2 1.62
BDDD0020 812813.7879 1099570.603 406.029 DD 315 -60 85 6 38.7 44.7 6 1.81
BDDD0020 812813.7879 1099570.603 406.029 DD 315 -60 85 2 65 67 2 3.51
BDDD0020 812813.7879 1099570.603 406.029 DD 315 -60 85 5 70 75 5 28.56
BDDD0021 812743.013 1099485.675 403.557 DD 315 -60 131 10 76 86 10 9.14
BDDD0021 812743.013 1099485.675 403.557 DD 315 -60 131 9 116 125 9 17.88
BDDD0022 812868.5546 1099613.494 406.306 DD 315 -60 120.6 7 18 25 7 6.92
BDDD0022 812868.5546 1099613.494 406.306 DD 315 -60 120.6 3 28 31 3 2.33
BDDD0022 812868.5546 1099613.494 406.306 DD 315 -60 120.6 8 34 42 8 2.53
BDDD0022 812868.5546 1099613.494 406.306 DD 315 -60 120.6 12 74 86 12 6.01
BDDD0022 812868.5546 1099613.494 406.306 DD 315 -60 120.6 5 109 114 5 1.77
BDRC0467 812526.3228 1099345.64 396.682 RC 315 -60 60 10 7 17 10 3.95
BDRC0467 812526.3228 1099345.64 396.682 RC 315 -60 60 8 30 38 8 2.93
BDRC0468 812565.2792 1099343.932 397.635 RC 315 -60 108 9 57 66 9 0.65
BDRC0468 812565.2792 1099343.932 397.635 RC 315 -60 108 8 100 108 8 1.21
BDRC0469 812540.5257 1099333.769 397.206 RC 315 -60 88 10 27 37 10 4.19
BDRC0469 812540.5257 1099333.769 397.206 RC 315 -60 88 14 41 55 14 3.21
BDRC0469 812540.5257 1099333.769 397.206 RC 315 -60 88 19 68 87 19 1.59
BDRC0470 812587.9661 1099355.248 397.96 RC 315 -60 84 6 48 54 6 0.75
BDRC0470 812587.9661 1099355.248 397.96 RC 315 -60 84 16 66 82 16 1.32
BDRC0471 812573.1173 1099370.785 398.182 RC 315 -60 90 44 12 56 44 2.37
BDRC0471 812573.1173 1099370.785 398.182 RC 315 -60 90 6 59 65 6 1.58
BDRC0472 812560.2619 1099383.802 398.234 RC 315 -60 60 6 17 23 6 6.01
BDRC0473 812597.3899 1099417.361 399.139 RC 315 -60 60 14 0 14 14 3.02
BDRC0473 812597.3899 1099417.361 399.139 RC 315 -60 60 6 26 32 6 1.34
BDRC0474 812610.5036 1099404.53 399.225 RC 315 -60 90 32 33 65 32 4.03
BDRC0475 812661.7976 1099425.153 400.66 RC 315 -60 60 8 49 57 8 3.02
BDRC0476 812648.7753 1099438.071 400.488 RC 315 -60 60 11 0 11 11 0.82
BDRC0476 812648.7753 1099438.071 400.488 RC 315 -60 60 2 25 27 2 2.29
BDRC0476 812648.7753 1099438.071 400.488 RC 315 -60 60 11 34 45 11 2.19

30

==> picture [114 x 35] intentionally omitted <==

BDRC0477 812625.3544 1099390.258 399.311 RC 315 -60 72 3 30 33 3 1.47
BDRC0478 812669.2045 1099487.074 402.086 RC 315 -60 60 NSI
BDRC0479 812683.1534 1099472.809 402.053 RC 315 -60 100 21 29 50 21 4.43
BDRC0479 812683.1534 1099472.809 402.053 RC 315 -60 100 4 68 72 4 1.36
BDRC0479 812683.1534 1099472.809 402.053 RC 315 -60 100 8 76 84 8 0.65
BDRC0479 812683.1534 1099472.809 402.053 RC 315 -60 100 4 91 95 4 1.14
BDRC0480 812698.1242 1099457.855 402.146 RC 315 -60 96 10 65 75 10 3.43
BDRC0480 812698.1242 1099457.855 402.146 RC 315 -60 96 18 78 96 18 8.42
BDRC0481 812709.2144 1099515.87 403.22 RC 315 -60 54 17 18 35 17 2.74
BDRC0481 812709.2144 1099515.87 403.22 RC 315 -60 54 4 40 44 4 1.13
BDRC0482 812729.3568 1099531.78 404.032 RC 315 -60 60 4 0 4 4 1.68
BDRC0482 812729.3568 1099531.78 404.032 RC 315 -60 60 2 13 15 2 3.46
BDRC0482 812729.3568 1099531.78 404.032 RC 315 -60 60 4 19 23 4 3.88
BDRC0482 812729.3568 1099531.78 404.032 RC 315 -60 60 5 45 50 5 2.08
BDRC0483 812743.2985 1099518.076 404.224 RC 315 -60 90 15 42 57 15 2.5
BDRC0483 812743.2985 1099518.076 404.224 RC 315 -60 90 28 61 89 28 1.22
BDRC0484 812819.8556 1099583.456 406.179 RC 315 -60 84 14 0 14 14 3.35
BDRC0484 812819.8556 1099583.456 406.179 RC 315 -60 84 14 17 31 14 1.23
BDRC0484 812819.8556 1099583.456 406.179 RC 315 -60 84 8 55 63 8 1.36
BDRC0485 812832.4142 1099570.32 406.179 RC 315 -60 120 14 17 31 14 0.92
BDRC0485 812832.4142 1099570.32 406.179 RC 315 -60 120 8 93 101 8 3.42
BDRC0486 812846.6874 1099556.057 406.216 RC 315 -60 102 12 43 55 12 2.16
BDRC0487 812859.5109 1099542.713 406.114 RC 315 -60 92 3 68 71 3 2.01
BDRC0488 812885.9198 1099553.332 406.455 RC 315 -60 90 8 77 85 8 2.36
BDRC0489 812868.3495 1099643.93 406.056 RC 315 -60 84 15 0 15 15 1.16
BDRC0489 812868.3495 1099643.93 406.056 RC 315 -60 84 11 23 34 11 1.25
BDRC0489 812868.3495 1099643.93 406.056 RC 315 -60 84 2 61 63 2 4.19
BDRC0490 812882.8085 1099628.628 406.242 RC 315 -60 120 10 19 29 10 3.27
BDRC0490 812882.8085 1099628.628 406.242 RC 315 -60 120 16 98 114 16 1.89
BDRC0490 812882.8085 1099628.628 406.242 RC 315 -60 120 2 118 120 2 3.05
BDRC0491 812897.0801 1099613.551 406.422 RC 315 -60 72 13 44 57 13 2.63
BDRC0492 812872.8244 1099672.186 406.003 RC 315 -60 50 9 9 18 9 4.09
BDRC0492 812872.8244 1099672.186 406.003 RC 315 -60 50 5 23 28 5 1.9

31

==> picture [114 x 35] intentionally omitted <==

BDRC0493 812931.0512 1099647.769 406.139 RC 315 -60 72 2 50 52 2 3.92
BDRC0494 812910.7376 1099599.37 406.728 RC 315 -60 84 10 66 76 10 1.87
BDRC0495 812916.0652 1099662.737 405.922 RC 315 -60 66 4 24 28 4 2.31
BDRC0496 812901.5067 1099677.113 405.816 RC 315 -60 88 10 0 10 10 1.03
BDRC0496 812901.5067 1099677.113 405.816 RC 315 -60 88 11 73 84 11 4.12
BDRC0497 812948.7955 1099703.111 405.347 RC 315 -60 68 12 21 33 12 8.32
BDRC0498 812934.8594 1099717.895 405.367 RC 315 -60 84 13 1 14 13 0.36
BDRC0498 812934.8594 1099717.895 405.367 RC 315 -60 84 10 52 62 10 1.78
BDRC0499 812959.3182 1099688.785 405.558 RC 315 -60 72 NSI
BDRC0500 812483.7937 1099248.44 395.101 RC 315 -60 72 NSI
BDRC0501 812497.969 1099235.284 394.979 RC 315 -60 72 NSI
BDRC0502 812487.7227 1099315.892 396.269 RC 315 -60 60 8 0 8 8 1.03
BDRC0502 812487.7227 1099315.892 396.269 RC 315 -60 60 7 15 22 7 1.02
BDRC0503 812516.5324 1099287.934 396.02 RC 315 -60 78 3 18 21 3 8.21
BDRC0503 812516.5324 1099287.934 396.02 RC 315 -60 78 2 24 26 2 2.66
BDRC0503 812516.5324 1099287.934 396.02 RC 315 -60 78 7 62 69 7 1.26
BDRC0504 812531.5644 1099272.914 395.982 RC 315 -60 72 NSI
BDRC0505 812502.4502 1099301.501 396.118 RC 315 -60 60 5 0 5 5 0.81
BDRC0505 812502.4502 1099301.501 396.118 RC 315 -60 60 10 10 20 10 7.13
BDRC0505 812502.4502 1099301.501 396.118 RC 315 -60 60 11 32 43 11 3.22
BDRC0506 812507.1177 1099332.976 396.731 RC 315 -60 60 4 23 27 4 1.39
BDRC0507 812555.5331 1099318.65 396.955 RC 315 -60 60 11 47 58 11 2.45
BDRC0508 812844.5495 1099523.051 405.802 RC 315 -60 84 5 25 30 5 1.1
BDRC0508 812844.5495 1099523.051 405.802 RC 315 -60 84 4 68 72 4 1.3
BDRC0509 812829.5005 1099504.075 405.224 RC 315 -60 92 4 68 72 4 1.85
BDRC0510 812792.4239 1099506.294 404.816 RC 315 -60 60 4 26 30 4 3
BDRC0510 812792.4239 1099506.294 404.816 RC 315 -60 60 12 41 53 12 0.96
BDRC0511 812787.0759 1099475.068 404.275 RC 315 -60 78 NSI
BDRC0512 812769.4617 1099491.955 404.152 RC 315 -60 60 NSI
BDRC0513 812755.8804 1099505.459 404.054 RC 315 -60 95 24 70 94 24 3.33
BDRC0514 812982.7944 1099674.83 405.943 RC 315 -60 96 NSI
BDRC0515 812948.1058 1099634.939 406.368 RC 315 -60 96 4 77 81 4 3.52
BDRC0516WO 812956.7206 1099787.466 405.067 RC 0 -90 80 18 7 25 18 0.92

32

==> picture [114 x 35] intentionally omitted <==

BDRC0516WO 812956.7206 1099787.466 405.067 RC 0 -90 80 19 29 48 19 0.67
BDRC0517WP 812948.6263 1099773.616 404.763 RC 0 -90 90 11 7 18 11 0.86
BDRC0517WP 812948.6263 1099773.616 404.763 RC 0 -90 90 9 51 60 9 0.8
BDRC0517WP 812948.6263 1099773.616 404.763 RC 0 -90 90 5 69 74 5 1.66
VÉRONIQUE
BDAC001678 816539.821 1083594.096 377.7134 AC 45 -60 25 NSI
BDAC001679 816525.5934 1083579.869 378.0794 AC 45 -60 42 NSI
BDAC001680 816525.3149 1083606.088 378.0564 AC 45 -60 25 NSI
BDAC001681 816513.4974 1083590.721 378.2814 AC 45 -60 36 NSI
BDAC001682 816497.2559 1083579.639 378.7344 AC 45 -60 54 5 43 48 5 13.64
BDAC001683 816540.6994 1083567.574 378.0264 AC 45 -60 42 8 24 32 8 1.34
BDAC001684 816558.9725 1083582.854 377.2044 AC 45 -60 25 8 0 8 8 2.05
BDAC001685 816556.6837 1083555.421 377.7714 AC 45 -60 42 8 24 32 8 1.28
BDAC001686 816569.947 1083569.937 377.2864 AC 45 -60 25 5 1 6 5 0.85
BDAC001686 816569.947 1083569.937 377.2864 AC 45 -60 25 15 10 25 15 2.64
BDAC001687 816483.3779 1083594.732 378.7294 AC 45 -60 54 33 0 33 33 2.94
BDAC001687 816483.3779 1083594.732 378.7294 AC 45 -60 54 4 38 42 4 2.5
BDAC001688 816498.1062 1083609.501 378.3784 AC 45 -60 36 14 22 36 14 6.29
BDAC001689 816478.5511 1083618.703 378.4964 AC 45 -60 36 7 23 30 7 3.3
BDAC001690 816463.9185 1083603.822 379.1134 AC 45 -60 54 8 37 45 8 3.25
BDAC001691 816467.64 1083635.105 378.4164 AC 45 -60 30 5 18 23 5 5.67
BDAC001692 816436.3388 1083632.979 379.2084 AC 45 -60 54 2 37 39 2 3.77
BDAC001693 816449.5779 1083646.692 378.8094 AC 45 -60 36 6 24 30 6 1.91
BDAC001694 816418.925 1083644.646 379.4964 AC 45 -60 54 5 42 47 5 1.71
BDAC001695 816435.8467 1083658.332 379.1804 AC 45 -60 36 11 25 36 11 5.15
BDDD0010 816450.8132 1083615.599 379.3004 DD 45 -60 49 9 36 43 7 5.22
BDDD0011 816556.7105 1083443.333 379.0794 DD 45 -50 98.8 NSI
BDDD0012 816450.4279 1083704.262 378.8654 DD 225 -50 80 NSI
BDDD0023 816622.5165 1083453.924 377.107 DD 45 -60 75 NSI
BDDD0024 816569.5427 1083482.178 378.272 DD 45 -60 85 NSI
BDDD0025 816380.5154 1083692.403 380.598 DD 45 -60 72 3 40 43 3 1.98
BDDD0026 816067.1708 1083907.77 378.071 DD 45 -60 42.5 13 27 40 13 1.43
BDRC0266 816543.4333 1083541.212 378.2444 RC 45 -60 60 NSI

33

==> picture [114 x 35] intentionally omitted <==

BDRC0267 816526.6224 1083524.707 378.7494 RC 45 -60 78 NSI
BDRC0268 816527.2002 1083552.404 378.4324 RC 45 -60 60 11 40 51 11 1.18
BDRC0269 816512.5035 1083538.577 378.7584 RC 45 -60 73 10 55 65 10 2.25
BDRC0270 816496.0257 1083551.23 379.0364 RC 45 -60 60 NSI
BDRC0271 816556.3701 1083525.682 378.2524 RC 45 -60 60 4 44 48 4 8.2
BDRC0272 816571.2407 1083513.686 378.1474 RC 45 -60 66 3 47 50 3 3.36
BDRC0273 816588.0782 1083503.097 377.7894 RC 45 -60 66 3 47 50 3 2.53
BDRC0274 816605.3017 1083491.93 377.5184 RC 45 -60 66 NSI
BDRC0275 816621.3178 1083478.894 377.1904 RC 45 -60 66 NSI
BDRC0276 816639.5029 1083470.326 376.7494 RC 45 -60 60 3 46 49 3 2.86
BDRC0277 816651.1332 1083451.509 376.2874 RC 45 -60 64 3 46 49 3 3.59
BDRC0278 816664.4044 1083434.344 375.9764 RC 45 -60 66 NSI
BDRC0279 816665.0553 1083409.381 376.0884 RC 45 -60 66 NSI
BDRC0280 816480.7689 1083563.304 379.2004 RC 45 -60 72 6 56 62 6 8.36
BDRC0281 816494.9769 1083551.602 378.9444 RC 45 -60 72 12 57 69 12 1.32
BDRC0282 816467.7583 1083579.895 379.4304 RC 45 -60 72 3 54 57 3 1.4
BDRC0283 816450.9692 1083590.709 379.7674 RC 45 -60 72 5 53 58 5 8.74
BDRC0284 816435.4929 1083574.848 379.8984 RC 45 -60 84 NSI
BDRC0285 816441.0463 1083608.693 379.6584 RC 45 -60 66 7 46 53 7 2
BDRC0286 816422.1839 1083618.477 379.9724 RC 45 -60 72 NSI
BDRC0287 816407.6421 1083604.329 380.4504 RC 45 -60 84 NSI
BDRC0288 816403.7861 1083632.335 380.1094 RC 45 -60 72 3 62 65 3 1.42
BDRC0289 816389.7674 1083617.822 380.7494 RC 45 -60 84 NSI
BDRC0290 816387.1397 1083637.617 380.4864 RC 45 -60 78 NSI
BDRC0291 816382.1442 1083662.016 380.4744 RC 45 -60 72 5 53 58 5 3.97
BDRC0292 816364.7285 1083646.887 381.1894 RC 45 -60 72 NSI
BDRC0293 816360.6835 1083666.267 381.2324 RC 45 -60 80 2 60 62 2 4.77
BDRC0293 816360.6835 1083666.267 381.2324 RC 45 -60 80 2 70 72 2 4.57
BDRC0294 816352.2831 1083686.086 381.5554 RC 45 -60 72 4 60 64 4 3.14
BDRC0295 816336.4533 1083671.626 382.4304 RC 45 -60 80 3 69 72 3 5.1
BDRC0295 816336.4533 1083671.626 382.4304 RC 45 -60 80 4 76 80 4 2.96
BDRC0296 816334.7448 1083700.263 381.8684 RC 45 -60 70 2 51 53 2 2.95
BDRC0296 816334.7448 1083700.263 381.8684 RC 45 -60 70 3 58 61 3 11.96

34

==> picture [114 x 35] intentionally omitted <==

BDRC0297 816320.538 1083686.384 382.6234 RC 45 -60 80 8 71 79 8 0.62
BDRC0298 816305.5729 1083700.795 382.4584 RC 45 -60 80 NSI
BDRC0299 816303.7493 1083730.528 381.7844 RC 45 -60 65 9 49 58 9 3.68
BDRC0300 816288.6603 1083739.482 381.7234 RC 45 -60 65 8 37 45 8 5.25
BDRC0301 816272.5628 1083752.996 381.6144 RC 45 -60 65 2 48 50 2 4.79
BDRC0302 816248.6282 1083759.258 381.8704 RC 45 -60 66 9 52 61 9 0.47
BDRC0303 816241.3141 1083778.475 381.5194 RC 45 -60 60 18 40 58 18 1.23
BDRC0304 816226.7455 1083764.045 382.1774 RC 45 -60 80 7 63 70 7 1.19
BDRC0305 816211.808 1083780.094 381.9564 RC 45 -60 80 NSI
BDRC0306 816227.7599 1083793.689 381.1344 RC 45 -60 65 2 21 23 2 5.31
BDRC0306 816227.7599 1083793.689 381.1344 RC 45 -60 65 6 37 43 6 1.28
BDRC0307 816213.6666 1083808.008 380.8954 RC 45 -60 65 9 18 27 9 2.35
BDRC0307 816213.6666 1083808.008 380.8954 RC 45 -60 65 3 44 47 3 2.25
BDRC0308 816197.5417 1083821.529 380.4674 RC 45 -60 65 7 37 44 7 1.08
BDRC0309 816180.727 1083793.564 381.5674 RC 45 -60 65 NSI
BDRC0310 816183.3305 1083833.211 380.0054 RC 45 -60 65 NSI
BDRC0311 816170.1381 1083817.792 380.6624 RC 45 -60 80 NSI
BDRC0312 816157.937 1083806.27 380.9164 RC 45 -60 65 NSI
BDRC0313 816677.8297 1083312.593 377.2914 RC 45 -60 84 6 51 57 6 1.14
BDRC0314 816154.7049 1083836.813 379.9724 RC 45 -60 80 NSI
BDRC0315 816363.4869 1083648.756 381.2894 RC 45 -60 86 2 70 72 2 3.24
BDRC0316 816577.1174 1083462.501 378.4984 RC 45 -60 102 NSI
BDRC0317 816619.23 1083421.243 377.1374 RC 45 -60 102 NSI
BDRC0318 816611.4164 1083444.731 377.3434 RC 45 -60 96 2 79 81 2 4.42
BDRC0319 816594.1886 1083450.238 377.8604 RC 45 -60 102 NSI
BDRC0320 816591.1952 1083476.793 377.9404 RC 45 -60 84 NSI
BDRC0321 816556.6061 1083499.188 378.5784 RC 45 -60 84 2 62 64 2 2.88
BDRC0322 816573.2493 1083485.028 378.3854 RC 45 -60 84 NSI
BDRC0323 816542.0349 1083512.445 378.8084 RC 45 -60 78 NSI
BDRC0324 816608.7187 1083464.058 377.7034 RC 45 -60 84 2 66 68 2 2.75
BDRC0346 816451.5468 1083672.64 378.9934 RC 45 -60 25 NSI
BDRC0347 816415.9436 1083667.696 379.5484 AC 45 -60 48 8 30 38 8 1.79
BDRC0348 816437.578 1083694.566 379.1124 RC 45 -60 18 NSI

35

==> picture [114 x 35] intentionally omitted <==

BDRC0349 816398.3671 1083677.581 379.9974 RC 45 -60 54 4 34 38 4 1.08
BDRC0350 816408.7104 1083692.95 379.8554 RC 45 -60 36 NSI
BDRC0351 816423.375 1083707.733 379.4484 RC 45 -60 25 NSI
BDRC0352 816387.2094 1083698.834 380.4684 RC 45 -60 50 10 27 37 10 3.22
BDRC0353 816402.4444 1083711.83 380.1304 RC 45 -60 35 6 12 18 6 5.24
BDRC0354 816366.7731 1083699.089 380.9774 RC 45 -60 55 3 41 44 3 4.54
BDRC0355 816382.677 1083713.316 380.3644 RC 45 -60 42 10 20 30 10 6.16
BDRC0356 816397.6369 1083728.649 379.9804 RC 45 -60 30 9 0 9 9 0.66
BDRC0357 816351.172 1083717.266 381.1164 RC 45 -60 55 10 30 40 10 4
BDRC0358 816365.2246 1083732.792 380.5684 RC 45 -60 42 9 17 26 9 3.89
BDRC0359 816376.1724 1083742.849 380.0164 RC 45 -60 30 7 0 7 7 1.49
BDRC0359 816376.1724 1083742.849 380.0164 RC 45 -60 30 4 13 17 4 2.06
BDRC0360 816334.4108 1083729.278 381.1924 RC 45 -60 55 2 35 37 2 3.04
BDRC0361 816348.1607 1083742.92 380.6544 RC 45 -60 42 NSI
BDRC0362 816362.3406 1083756.169 380.0814 RC 45 -60 30 25 0 25 25 3.05
BDRC0363 816334.8639 1083757.351 380.6894 RC 45 -60 40 15 20 35 15 2.6
BDRC0364 816348.0737 1083770.285 380.2344 RC 45 -60 30 11 9 20 11 1.04
BDRC0365 816320.4717 1083743.754 381.2674 RC 45 -60 50 3 40 43 3 5.14
BDRC0366 816305.6434 1083755.573 381.0624 RC 45 -60 50 6 37 43 6 18.27
BDRC0367 816316.9715 1083768.455 380.7404 RC 45 -60 40 10 26 36 10 3.93
BDRC0368 816329.6619 1083781.803 380.2944 RC 45 -60 30 NSI
BDRC0369 816285.2168 1083770.545 381.1074 RC 45 -60 45 4 33 37 4 11.08
BDRC0370 816300.2295 1083783.68 380.6714 RC 45 -60 30 9 20 29 9 8.09
BDRC0371 816316.3852 1083799.785 380.4224 RC 45 -60 20 4 7 11 4 2.65
BDRC0372 816294.3253 1083802.877 380.5024 RC 45 -60 25 6 17 23 6 0.88
BDRC0373 816277.1862 1083786.193 381.0424 RC 45 -60 40 NSI
BDRC0374 816256.9966 1083794.107 380.8494 RC 45 -60 45 10 25 35 10 1.07
BDRC0375 816270.3129 1083810.204 380.6874 RC 45 -60 30 8 12 20 8 2.66
BDRC0376 816243.2728 1083807.844 380.6844 RC 45 -60 45 5 27 32 5 1.31
BDRC0377 816259.3667 1083822.049 380.5164 RC 45 -60 30 4 9 13 4 1.15
BDRC0377 816259.3667 1083822.049 380.5164 RC 45 -60 30 4 16 20 4 5.63
BDRC0378 816229.7704 1083820.826 380.3794 RC 45 -60 45 2 23 25 2 2.15
BDRC0378 816229.7704 1083820.826 380.3794 RC 45 -60 45 5 28 33 5 0.89

36

==> picture [114 x 35] intentionally omitted <==

BDRC0379 816243.0972 1083833.08 380.2644 RC 45 -60 30 4 16 20 4 2.13
BDRC0380 816226.3169 1083848.851 379.9754 RC 45 -60 30 NSI
BDRC0381 816199.0324 1083850.291 379.7214 RC 45 -60 45 NSI
BDRC0382 816211.8886 1083862.153 379.6484 RC 45 -60 30 NSI
BDRC0383 816186.8578 1083864.378 379.3634 RC 45 -60 45 8 13 21 8 1.24
BDRC0384 816200.2925 1083876.726 379.1624 RC 45 -60 30 NSI
BDRC0385 816173.5398 1083876.919 379.0674 RC 45 -60 45 2 10 12 2 2.03
BDRC0386 816188.3823 1083890.653 378.9904 RC 45 -60 30 21 0 21 21 2.86
BDRC0387 816169.308 1083902.754 378.7104 RC 45 -60 35 NSI
BDRC0388 816151.4066 1083912.415 378.3624 RC 45 -60 45 NSI
BDRC0389 816121.1473 1083883.089 378.9084 RC 45 -60 40 9 18 27 9 0.61
BDRC0390 816107.2002 1083869.061 379.0154 RC 45 -60 50 4 35 39 4 2.41
BDRC0391 816120.4537 1083911.333 378.3604 RC 45 -60 25 8 5 13 8 0.63
BDRC0391 816120.4537 1083911.333 378.3604 RC 45 -60 25 4 18 22 4 1.04
BDRC0392 816106.5005 1083897.016 378.5074 RC 45 -60 42 4 21 25 4 2.01
BDRC0393 816092.557 1083884.599 378.6004 RC 45 -60 54 4 32 36 4 1.13
BDRC0394 816104.5865 1083924.001 378.0484 RC 45 -60 30 5 7 12 5 0.97
BDRC0395 816091.0866 1083911.753 378.2144 RC 45 -60 50 8 13 21 8 1.46
BDRC0396 816076.4067 1083898.366 378.2164 RC 45 -60 60 7 28 35 7 1.04
BDRC0397 816058.0369 1083903.174 378.0734 RC 45 -60 50 NSI
BDRC0398 816043.5085 1083919.268 377.5754 RC 45 -60 50 NSI
BDRC0399 816029.4628 1083933.009 377.0154 RC 45 -60 50 NSI
BDRC0400 816014.8208 1083945.052 376.7934 RC 45 -60 50 NSI
BDRC0401 816030.2327 1083961.569 376.5004 RC 45 -60 40 NSI
BDRC0402 816044.5632 1083976.555 376.4994 RC 45 -60 30 NSI
BDRC0403 816040.5289 1083949.642 376.8864 RC 45 -60 40 NSI
BDRC0404 816054.9137 1083960.091 376.8534 RC 45 -60 30 NSI
BDRC0405 816072.5041 1083946.052 377.4134 RC 45 -60 30 NSI
BDRC0406 816081.1038 1083931.302 377.7134 RC 45 -60 30 6 8 14 6 1.96
BDRC0407 816060.1396 1083939.073 377.3574 RC 45 -60 40 NSI
BDRC0408 816164.1358 1083925.939 378.1654 RC 45 -60 30 NSI
BDRC0409 816570.1458 1083541.67 377.8334 RC 45 -60 42 2 28 30 2 17.38
BDRC0410 816585.5006 1083555.41 377.1774 RC 45 -60 25 6 13 19 6 4.69

37

==> picture [114 x 35] intentionally omitted <==

BDRC0411 816584.7109 1083527.204 377.5554 RC 45 -60 42 2 32 34 2 7.73
BDRC0412 816600.0452 1083541.038 377.1584 RC 45 -60 25 4 16 20 4 12.83
BDRC0413 816618.1147 1083529.957 376.7824 RC 45 -60 25 5 18 23 5 2.81
BDRC0414 816602.2018 1083516.802 377.4294 RC 45 -60 42 3 32 35 3 2.87
BDRC0415 816630.0063 1083517.943 376.7434 RC 45 -60 25 NSI
BDRC0416 816618.3103 1083505.597 377.2904 RC 45 -60 45 5 32 37 5 3.15
BDRC0417 816647.9169 1083506.463 376.2884 RC 45 -60 25 NSI
BDRC0418 816635.0428 1083493.516 376.7534 RC 45 -60 42 3 34 37 3 4.14
BDRC0419 816663.1311 1083495.471 376.4524 RC 45 -60 25 NSI
BDRC0420 816675.8152 1083478.105 375.4874 RC 45 -60 25 NSI
BDRC0421 816692.0807 1083462.652 375.0674 RC 45 -60 25 3 22 25 3 4.33
BDRC0422 816690.8241 1083436.669 375.2304 RC 45 -60 25 NSI
BDRC0423 816674.9337 1083420.156 375.7294 RC 45 -60 42 NSI
BDRC0424 816660.6094 1083465.601 376.0324 RC 45 -60 42 3 31 34 3 1.43
BDRC0425 816677.1841 1083448.147 375.3274 RC 45 -60 45 NSI
BDRC0426 816685.7678 1083402.718 375.6624 RC 45 -60 39 NSI
BDRC0427 816702.2211 1083416.919 375.2064 RC 45 -60 25 NSI
BDRC0428 816707.1355 1083391.611 375.4824 RC 45 -60 25 NSI
BDRC0429 816693.6287 1083379.864 375.8284 RC 45 -60 42 NSI
BDRC0430 816713.977 1083372.081 375.7684 RC 45 -60 25 NSI
BDRC0431 816698.3095 1083357.463 376.1194 RC 45 -60 42 2 10 12 2 3.72
BDRC0432 816708.5902 1083338.102 376.3214 RC 45 -60 42 NSI
BDRC0433 816508.8928 1083618.455 378.2684 RC 45 -60 25 6 14 20 6 2.15
BDRC0434 816495.2075 1083632.876 378.2954 RC 45 -60 25 3 10 13 3 35.66
BDRC0435 816464.7514 1083661.305 378.7434 RC 45 -60 25 NSI
BDRC0436 816091.4219 1083854.404 379.2444 RC 45 -60 60 NSI
BDRC0437 816076.3187 1083868.284 378.882 RC 45 -60 60 NSI
BDRC0438 816066.3703 1083883.436 378.6514 RC 45 -60 60 NSI
BDRC0439 816133.2789 1083894.766 378.7344 RC 45 -60 60 NSI
BDRC0440 816146.8242 1083880.12 378.9064 RC 45 -60 65 6 16 22 6 1.08
BDRC0441 816110.4829 1083845.602 379.6044 RC 45 -60 66 NSI
BDRC0442 816131.0657 1083837.08 379.8354 RC 45 -60 65 4 50 54 4 1.54
BDRC0443 816155.3369 1083864.72 379.1274 RC 45 -60 60 NSI

38

==> picture [114 x 35] intentionally omitted <==

BDRC0444 816139.4104 1083821.56 380.4074 RC 45 -60 65 NSI
BDRC0445 816171.2126 1083850.326 379.6624 RC 45 -60 66 4 27 31 4 1.42
BDRC0446 816140.9616 1083849.312 379.6364 RC 45 -60 72 NSI
BDRC0447 816670.1268 1083387.137 376.2284 RC 45 -60 66 10 7 17 10 1.14
BDRC0448 816678.0824 1083366.711 376.5314 RC 45 -60 66 5 18 23 5 1.56
BDRC0449 816685.0781 1083344.938 376.5574 RC 45 -60 66 NSI
BDRC0450 816693.319 1083325.82 376.9024 RC 45 -60 66 4 30 34 4 4.25
BDRC0451 816670.2082 1083330.166 376.9474 RC 45 -60 84 7 40 47 7 0.99
BDRC0452 816662.8432 1083350.924 376.8564 RC 45 -60 84 NSI
BDRC0453 816657.2853 1083372.64 376.7104 RC 45 -60 84 7 27 34 7 0.95
BDRC0454 816650.5117 1083392.517 376.7914 RC 45 -60 84 NSI
BDRC0455 816648.519 1083421.318 376.4234 RC 45 -60 84 4 4 8 4 1.01
BDRC0456 816636.8221 1083437.315 376.6894 RC 45 -60 84 20 64 84 20 1.44
BDRC0457 816609.9188 1083465.379 377.6284 RC 45 -60 72 2 67 69 2 5.72
BDRC0520 816566.7314 1083565.426 377.527 RC 45 -60 28 5 14 19 5 1.91
BDRC0521 816476.9508 1083591.746 379.061 RC 45 -60 54 6 42 48 6 1.93
BDRC0522WP 816255.8584 1083713.866 383.453 RC 0 -90 97 NSI
BDRC0524WP 816267.1482 1083703.978 383.395 RC 0 -90 70 NSI
JULIETTE
BDAC001714 810645.7503 1096765.118 370.066 AC 315 -55 48 15 12 27 15 1.76
BDAC001714 810645.7503 1096765.118 370.066 AC 315 -55 48 3 44 47 3 1.91
BDAC001715 810661.4763 1096780.005 369.827 AC 315 -55 46 8 16 24 8 1.14
BDAC001716 810677.9133 1096802.496 370.277 AC 315 -55 38 8 6 14 8 0.79
BDAC001716 810677.9133 1096802.496 370.277 AC 315 -55 38 7 19 26 7 1.93
BDAC001717 810696.978 1096818.103 370.19 AC 315 -55 35 23 10 33 23 1.28
BDAC001718 810710.3658 1096838.277 369.931 AC 315 -55 30 14 9 23 14 1.88
BDAC001719 810745.0375 1096877.54 370.016 AC 315 -55 30 12 11 23 12 1.04
BDAC001720 810760.9231 1096897.028 369.775 AC 315 -55 30 9 8 17 9 0.77
BDAC001721 810776.3322 1096918.242 369.533 AC 315 -55 30 5 10 15 5 1.57
BDAC001722 810805.0841 1096954.6 369.456 AC 315 -55 30 3 11 14 3 2.31
BDAC001723 810726.3099 1096860.069 370.058 AC 315 -55 30 9 6 15 9 5.44
BDAC001724 810791.506 1096935.531 369.477 AC 315 -55 30 9 9 18 9 2.33
BDAC001725 810819.3975 1096978.33 369.69 AC 315 -55 30 6 6 12 6 1.66

39

==> picture [114 x 35] intentionally omitted <==

BDAC001726 810836.672 1096994.078 369.87 AC 315 -55 30 5 15 20 5 0.94
BDAC001727 810851.5799 1097016.808 369.789 AC 315 -55 29 3 14 17 3 2.94
BDAC001728 810884.5568 1097053.399 369.886 AC 315 -55 30 9 11 20 9 1.89
BDAC001729 810901.8956 1097071.756 369.973 AC 315 -55 30 12 9 21 12 1.08
BDRC0325 810657.2652 1096753.905 369.686 RC 315 -55 73 15 36 51 15 3.3
BDRC0326 810667.6164 1096742.899 369.43 RC 315 -55 96 18 23 41 18 0.29
BDRC0326 810667.6164 1096742.899 369.43 RC 315 -55 96 12 55 67 12 2.55
BDRC0327 810819.4624 1096943.021 369.137 RC 315 -55 54 10 38 48 10 2.63
BDRC0328 810830.5601 1096934.954 368.781 RC 315 -55 78 9 52 61 9 1.78
BDRC0329 810830.3628 1096966.806 369.48 RC 315 -55 54 NSI
BDRC0330 810848.2076 1096984.049 369.475 RC 315 -55 54 8 37 45 8 2.71
BDRC0331 810863.4989 1097005.65 369.333 RC 315 -55 54 4 34 38 4 2.48
BDRC0332 810883.7785 1097020.869 369.575 RC 315 -55 66 7 52 59 7 7.78
BDRC0333 810906.8748 1097031.028 369.421 RC 315 -55 78 NSI
BDRC0334 810895.6072 1097042.266 369.73 RC 315 -55 54 9 39 48 9 0.6
BDRC0335 810913.8671 1097060.403 369.707 RC 315 -55 54 NSI
BDRC0336 810924.6915 1097048.114 369.348 RC 315 -55 84 NSI
BDRC0337 810875.3643 1096994.067 368.95 RC 315 -55 78 5 54 59 5 1.49
BDRC0338 810860.7219 1096972.024 369.159 RC 315 -55 84 6 64 70 6 2.08
BDRC0339 810798.2428 1096890.408 368.919 RC 315 -55 72 22 40 62 22 1.23
BDRC0340 810814.9189 1096911.362 368.845 RC 315 -55 78 16 48 64 16 1.52
BDRC0341 810804.2879 1096922.723 369.128 RC 315 -55 54 9 6 15 9 1.86
BDRC0341 810804.2879 1096922.723 369.128 RC 315 -55 54 8 34 42 8 1.9
BDRC0342 810782.2033 1096873.509 369.275 RC 315 -55 72 9 45 54 9 2.39
BDRC0343 810770.6076 1096884.648 369.398 RC 315 -55 56 13 26 39 13 1.1
BDRC0344 810755.4231 1096865.171 369.825 RC 315 -55 58 13 26 39 13 2.72
BDRC0345 810749.806 1096834.815 369.532 RC 315 -55 76 13 43 56 13 2.25
BDRC0458 810723.1232 1096827.907 369.73 RC 315 -55 60 5 36 41 5 3.16
BDRC0459 810769.6349 1096853.367 369.367 RC 315 -55 78 10 50 60 10 3.05
BDRC0460 810734.5278 1096813.908 369.385 RC 315 -55 81 NSI
BDRC0461 810709.9357 1096803.493 369.776 RC 315 -55 60 16 41 57 16 2.23
BDRC0462 810721.7034 1096795.033 369.697 RC 315 -55 84 5 68 73 5 1.03
BDRC0463 810689.0699 1096791.189 369.936 RC 315 -55 65 4 38 42 4 2.42

40

==> picture [114 x 35] intentionally omitted <==

BDRC0464 810686.4533 1096757.971 369.44 RC 315 -55 39 NSI
BDRC0465 810672.5804 1096767.613 369.541 RC 315 -55 60 18 39 57 18 1.58
BDRC0466 810686.752 1096759.986 369.435 RC 315 -55 92 19 59 78 19 2.19
BDRC0466 810686.752 1096759.986 369.435 RC 315 -55 92 5 85 90 5 0.86
BDRC0518WP 810592.5044 1096732.634 369.818 RC 0 -90 90 26 60 86 26 4.49
BDRC0519WO 810585.2157 1096717.169 369.59 RC 0 -90 6 NSI
BDRC0523WP 812448.5978 1099245.25 394.748 RC 0 -90 80 3 77 80 3 5.75

41

==> picture [114 x 35] intentionally omitted <==

APPENDIX B: JORC TABLE 1 – YAOURÉ GOLD PROJECT

Section 1 Sampling Techniques and Data

Criteria JORC Code explanation Commentary
Sampling
techniques
Nature and quality of sampling (e.g. cut
channels, random chips, or specific
specialised industry standard
measurement tools appropriate to the
minerals under investigation, such as
downhole gamma sondes, or handheld
XRF instruments, etc.). These examples
should not be taken as limiting the broad
meaning of sampling.

Include reference to measures taken to
ensure sample representivity and the
appropriate calibration of any
measurement tools or systems used.

Aspects of the determination of
mineralisation that are Material to the
Public Report.

In cases where ‘industry standard’ work
has been done this would be relatively
simple (e.g. ‘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 (e.g.
submarine nodules) may warrant
disclosure of detailed information.
Yaouré drill hole data derive from:
o
Air core (“kit-bit”) drill holes generally drilled at 4”
diameter;
o
Reverse circulation percussion (RC) holes generally
drilled at approximately 5¼” diameter using a face-
sampling hammer;
o
Diamond core holes generally drilled HQ diameter in
weathered materials and NQ or NQ2 diameter in
fresh rock;
o
Diamond core holes with RC pre-collars.

In all air core holes other than those drilled in the Y2 North area
samples were collected at 1m intervals, each 1m spear sampled
and the spear samples composited into 4m intervals.

Air core holes in the Y2 North area were sampled at 1m intervals
and riffle split to produce a subsample of 2.4 – 3kg for submission
for assay.

RC drill samples are collected at 1m intervals and riffle split to
produce a subsample of 2.5 – 4kg for submission for assay.

Diamond core samples are halved and one half submitted for
assay.

Air core holes are sampled in entirety.

RC and core holes drilled prior to 2017 were generally sampled in
entirety. Fill material encountered in 2017 holes and 2018 has
not been sampled.

RC and core holes drilled prior to 2017 were sampled in entirety,
including through mine backfill. In holes drilled in 2017 and 2018
backfill material has not been sampled. RC holes have been
otherwise sampled in entirety. Diamond core has been
selectively sampled through intervals displaying alteration and
mineralisation and for several metres above and below such
intervals.
Drilling
techniques
Drill type (e.g. core, reverse circulation,
open-hole hammer, rotary air blast, auger,
Bangka, sonic, etc.) and details (e.g. core
diameter, triple or standard tube, depth of
diamond tails, face-sampling bit or other
type, whether core is oriented and if so, by
what method, etc.).
Air core (“kit-bit”) drill holes generally drilled at 4” diameter;

Reverse circulation percussion (RC) holes generally drilled at
approximately 5¼” diameter using a face-sampling hammer.

Diamond core holes generally drilled HQ diameter in weathered
materials and NQ diameter in fresh rock.

Diamond core in weakly weathered and fresh rock is oriented by
means of digital orientation devices (Reflex tool or similar).
Drill sample
recovery
Method of recording and assessing core
and chip sample recoveries and results
assessed.

Measures taken to maximise sample
recovery and ensure representative nature
of the samples.

Whether a relationship exists between
sample recovery and grade and whether
sample bias may have occurred due to
preferential loss/gain of fine/coarse
material.
In all air core holes other than those drilled in the Y2 North area
samples recoveries were not measured.

Air core holes in the Y2 North area were sampled at 1m intervals
and riffle split to produce a subsample of 2.4 – 3kg for submission
for assay. Each entire recovered sample is weighed and each
subsample is weighed before and after drying. The condition
(dry, damp, wet) of each sample is recorded.

RC drill samples are collected at 1m intervals and riffle split to
produce a subsample of 2.5 – 4kg for submission for assay. Each
entire recovered sample is weighed and each subsample is
weighed before and after drying. The condition (dry, damp, wet)
of each sample is recorded.

Length of recovered diamond core is measured and recovery
calculated based on run length. Core recoveries in weathered

42

==> picture [114 x 35] intentionally omitted <==

Criteria JORC Code explanation Commentary
materials are generally greater than 85%; core recovery in fresh
rock is near 100%.

There is no evident relationship between sample recovery and
grade for diamond drilling.
Logging
Whether core and chip samples have been
geologically and geotechnically logged to a
level of detail to support appropriate
Mineral Resource estimation, mining
studies and metallurgical studies.

Whether logging is qualitative or
quantitative in nature. Core (or costean,
channel, etc.) photography.

The total length and percentage of the
relevant intersections logged.
Air core and RC drill samples are logged for weathering,
oxidation, rock type, alteration and mineralisation. Sieved chip
samples are retained in plastic trays for future reference and all
chip trays are photographed.

Prior to cutting, diamond drill core is logged for weathering,
oxidation, rock type, alteration, veining, mineralisation and
structure. Oriented core is also logged for geotechnical
parameters.

Whole core is photographed wet and dry.

Logging is considered appropriate and reliable.
Sub-sampling
techniques
and sample
preparation
If core, whether cut or sawn and whether
quarter, half or all core taken.

If non-core, whether riffled, tube sampled,
rotary split, etc. and whether sampled wet
or dry.

For all sample types, the nature, quality
and appropriateness of the sample
preparation technique.

Quality control procedures adopted for all
sub-sampling stages to maximise
representivity of samples.

Measures taken to ensure that the
sampling is representative of the in situ
material collected, including for instance
results for field duplicate/second-half
sampling.

Whether sample sizes are appropriate to
the grain size of the material being
sampled.
In all air core holes other than those drilled in the Y2 North area
samples were collected at 1m intervals, each 1m spear sampled
and the spear samples composited into 4m intervals.

Air core holes in the Y2 North area were sampled at 1m intervals
and riffle split to produce a subsample of 2.4 – 3kg for submission
for assay.

RC drill samples are collected at 1m intervals and riffle split to
produce a subsample of 2.5 – 4kg for submission for sample
preparation and assay. Each subsample is weighed before and
after drying.

Diamond core is sawn in half using a motorized diamond blade
saw; right half sent for assaying, left half stored in core trays for
reference. Core in weathered materials may be halved using a
knife or similar.

Perseus, and previously Amara, run an on-site sample
preparation laboratory. Both core and RC chips are dried,
crushed to -2mm and a riffle split portion of approximately 1.5kg
pulverised with a puck mill (LM2).

Quartz wash samples are used between every sample in both
crushing and pulverising stages.

The sample pulp is thoroughly mixed on a rolling mat and 200 g
of sub-sample collected. Internal laboratory checks are
undertaken to ensure a grind of at least 90% passing -75 µm is
maintained.

Sample pups are then packed into cardboard boxes for transport
to the assay laboratory.

The sampling and sub-sampling procedures are considered
appropriate and to meet or exceed industry norms.
Quality of
assay data
and
laboratory
tests
The nature, quality and appropriateness of
the assaying and laboratory procedures
used and whether the technique is
considered partial or total.

For geophysical tools, spectrometers,
handheld XRF instruments, etc., the
parameters used in determining the
analysis including instrument make and
model, reading times, calibrations factors
applied and their derivation, etc.

Nature of quality control procedures
adopted (e.g. standards, blanks, duplicates,
external laboratory checks) and
whether acceptable levels of accuracy (i.e.
lack of bias) and precision have been
established.
All air core, RC and core samples have been assayed by
commercial laboratories using 50g standard fire assay.

Duplicate field splits of air core RC samples are submitted at a
ratio of 1:25.

Field duplicates of core samples are not submitted.

Blanks inserted at 1:25.

Certified standards at 1:25

Quartz wash samples are routinely composited and assayed.

Internal laboratory standards, duplicates and repeats and various
other tests have been carried out throughout the drilling
programs.

Assays of reference standards and blanks are routinely monitored
and any laboratory batch that returns assays out of specification
is re-assayed in entirety.

Qualitycontrolprocedures are considered to exceed industry

==> picture [114 x 35] intentionally omitted <==

Criteria JORC Code explanation Commentary
norms.
Verification
of sampling
and assaying
The verification of significant intersections
by either independent or alternative
company personnel.

The use of twinned holes.

Documentation of primary data, data
entry procedures, data verification, data
storage (physical and electronic) protocols.

Discuss any adjustment to assay data.
Gold assays are routinely viewed in conjunction with geological
logs and sense checked against results from adjacent holes.

Drill logs and sample interval records are recorded on paper and
transcribed into digital form.

Digital data are imported into a relational database with inbuilt
validation routines.

All hard copies are filed on site.

Downhole survey data and collar survey data are provided by the
drilling contractors and surveyors respectively in digital format.

No adjustments have been made to assay data. The first assay
that fulfils QAQC hurdles is the primary database assay.
Location of
data points
Accuracy and quality of surveys used to
locate drill holes (collar and downhole
surveys), trenches, mine workings and
other locations used in Mineral Resource
estimation.

Specification of the grid system used.

Quality and adequacy of topographic
control.
All air core, RC and diamond core hole collar locations have been
surveyed by qualified company surveyors using differential GPS
equipment. Survey controls were established in 2007 by the
Bureau National d’Etudes Techniques et de Developpement
Centre de Cartographie et de Télédétection.

RC and diamond core holes drilled since 2012 have been down-
hole surveyed, generally at approximately 30 metre depth
increments, using single shot digital equipment. Down-hole
surveys are routinely sense checked.

Air core holes are not down-hole surveyed.

Grid system used is WGS84 UTM Zone 30N.
Data spacing
and
distribution
Data spacing for reporting of Exploration
Results.

Whether the data spacing and distribution
is sufficient to establish the degree of
geological and grade continuity
appropriate for the Mineral Resource and
Ore Reserve estimation procedure(s) and
classifications applied.

Whether sample compositing has been
applied.
After drilling completed in 2017 and 2018, drill spacing over the
Yaouré pit area is mostly 25m x 25m. Drill spacing over the CMA
deposit area is mostly 25m x 50m.

Drill hole spacing, in conjunction with open pit exposures, is
sufficient to reliably establish the orientation of mineralised
structures.

Sample intervals have not been composited prior to calculation
of exploration drill intercepts.
Orientation
of data in
relation to
geological
structure
Whether the orientation of sampling
achieves unbiased sampling of possible
structures and the extent to which this is
known, considering the deposit type.

If the relationship between the drilling
orientation and the orientation of key
mineralised structures is considered to
have introduced a sampling bias, this
should be assessed and reported if
material.
Drill holes are oriented so as to intersect the dominant lode
structures at a high angle and attain near true width drill
intercepts.

There are, however, in Yaouré pit a number of mineralised
structures that strike at an angle that is oblique to the orientation
of most drill holes.
Sample
security
The measures taken to ensure sample
security.
Samples from air core, RC and core drilling are processed through
an on-site sample preparation laboratory that is supervised by
highly experienced and professional Company employees.

Sample pulps are packed in securely fastened boxes that are, in
turn, packed in cartons for transport to commercial assay
laboratories.

Samples are normally transported from site to the commercial
laboratory by personnel of that laboratory.
Audits or
reviews
The results of any audits or reviews of
sampling techniques and data.
Assay data for holes drilled prior to 2017 were reviewed by Mario
E. Rossi FAusIMM of GeoSystems International Inc, the last time
being in December 2015.

Sampling techniques and assay data available at 12 September
2017 were reviewed byJonathon Abbott of MPR Geological

==> picture [114 x 35] intentionally omitted <==

  • Criteria JORC Code explanation Commentary Consultants Pty Ltd.

  • • Drill hole data and assays for drilling completed in 2018 have been reviewed and validated by Gary Brabham and Cissé Amadou, both employees of Perseus Mining.

Section 2 Reporting of Exploration Results - Yaouré

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

Criteria JORC Code Explanation Commentary
Mineral tenement
and land tenure
status		 Type, reference name/number, location and
ownership including agreements or material issues
with third parties such as joint ventures, partnerships,
overriding royalties, native title interests, historical
sites, wilderness or national park and environmental
settings.
The security of the tenure held at the time of
reporting along with any known impediments to
obtaining a licence to operate in the area.		 • Reported RC, AC and DD results from the Sayikro are within the
Yaouré exploitation permit (tenement PE50)
• The Yaouré exploitation permit has an expiry date of 23 April
2030. The permit is held by Perseus’s subsidiary Perseus
Mining Yaouré SA in which the government of Côte d’Ivoire
holds a 10% free carried interest. The Government of Côte
d’Ivoire is entitled to a royalty on production as follows:
Spot price per ounce - London PM Fix
Royalty
Rate
Less than or equal to US$1000
3%
Higher than US$1000 and less than or
equal to US$1300
3.5%
Higher than US$1300 and less than or
equal to US$1600
4%
Higher than US$1600 and less than or
equal to US$2000
5%
Higher than US$2000
6%
• The Allekran prospect lies within the Yaouré West Permis de
Recherche (tenement PR615).
• The Yaouré West PR has an expiry date of 29 September 2022.
The permit is held by Perseus’s subsidiary Perseus Yaouré sarl.
The Government of Côte d’Ivoire retains the right to take up
10% non-contributing beneficial ownership of any portion of
the PR that is converted to an exploitation permit.
• The reported exploration areas have no known exploration-
specific environmental liabilities.
Exploration done
by other parties		 Acknowledgment and appraisal of exploration by
other parties.		 • No previous drilling has been conducted on the Sayikro
prospect or at Allekran.
Geology Deposit type, geological setting and style of
mineralisation.		 • The Sayikro and Allekran prospects are underlain by mafic
volcanics intruded by granodiorite bodies.
• Mineralisation occurs as disseminations of py-apy in the
granodiorite and in qtz-carbonate veins in both the intrusives
and basalts.
• The three deep holes into the CMA thrust were designed to
identify the structure at depth.

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Drill hole
Information		 A summary of all information material to the
understanding of the exploration results including a
tabulation of the following information for all
Material drill holes:
o
easting and northing of the drill hole colla_r
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.		 • Reported results are summarised in Table 3 within the
attached announcement.
• The drill holes reported in this announcement have the
following parameters:
• Grid co-ordinates are UTM WGS84_30N.
• Collar elevation is defined as height above sea level in metres
(RL)
• Dip is the inclination of the hole from the horizontal. Azimuth is
reported in WGS 84_29N degrees as the direction toward
which the hole is drilled.
• Down hole length of the hole is the distance from the surface
to the end of the hole, as measured along the drill trace
• Intersection depth is the distance down the hole as measured
along the drill trace.
• Intersection width is the down hole distance of an intersection
as measured along the drill trace
• Hole length is the distance from the surface to the end of the
hole, as measured along the drill trace.
• Previously reported drilling results have not been repeated in
this announcement.
Data aggregation
methods		 In reporting Exploration Results, weighting averaging
techniques, maximum and/or minimum grade
truncations (e.g. 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.		 • A minimum cut-off grade of 0.3 g/t Au is applied to the
reported intervals.
• Intervals of Internal dilution (<0.3 g/t Au) within a reported
interval cannot exceed 2m.
• No grade top cut has been applied.
• Samples have been weighted by length of sample interval
• No metal equivalent reporting is used or applied.
Relationship
between
mineralisation
widths and
intercept lengths		 These relationships are 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 should be
reported.
If it is not known and only the down hole lengths are
reported, there should be a clear statement to this
effect (e.g. ‘down hole length, true width not
known’).		 • The reported results are from early stage exploration drilling;
the orientation of geological structures is currently not known
with certainty (other than the CMA).
• Results are reported as down hole length, true width is
unknown.
Diagrams Appropriate maps and sections (with scales) and
tabulations of intercepts should be included for any
significant discovery being reported These should
include, but not be limited to a plan view of drill hole
collar locations and appropriate sectional views.		 • Drill hole plans are shown in Figures 5 & 6 in Appendix A.
• Significant assay results are tabulated in body text of this
announcement
Balanced reporting Where comprehensive reporting of all Exploration
Results is not practicable, representative reporting of
both low and high grades and/or widths should be
practiced to avoid misleading reporting of
Exploration Results.		 • Results have been comprehensively reported in this
announcement.
• All drill holes completed, including holes with no significant
gold intersections, are reported in Table 3 of Appendix A.

34

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Other substantive
exploration data		 Other exploration data, if meaningful and material,
should be reported including (but not limited to):
geological observations; geophysical survey results;
geochemical survey results; bulk samples – size and
method of treatment; metallurgical test results; bulk
density, groundwater, geotechnical and rock
characteristics; potential deleterious or
contaminating substances.		 • There is no other exploration data which is considered material
to the results reported in this announcement
Further work The nature and scale of planned further work (e.g.
tests for lateral extensions or depth extensions or
large-scale step-out drilling).
Diagrams clearly highlighting the areas of possible
extensions, including the main geological
interpretations and future drilling areas, provided this
information is not commercially sensitive.		 • Further drilling is warranted at Sayikro to assess the gold within
both the mafic volcanics and the granodiorite, and to define
the strike length of the intersected mineralisation.
• Results from Akakro & Govisou are be assessed to determine
whether further drilling is warranted.
• Grade-control drilling is planned for Angovia 2 to quantify a
potential oxide resource.
• The CMA Deeps holes will be used for future down-hole
seismic measurements.
Diagrams Appropriate maps and sections (with scales) and
tabulations of intercepts should be included for any
significant discovery being reported These should
include, but not be limited to a plan view of drill hole
collar locations and appropriate sectional views.		 • Drill hole plans are shown in Figures 2 & 7. Assay results
are tabulated in body text of this announcement
Criteria JORC Code Explanation Commentary
Balanced reporting
Other substantive
exploration data		 Where comprehensive reporting of all Exploration
Results is not practicable, representative reporting of
both low and high grades and/or widths should be
practiced to avoid misleading reporting of
Exploration Results.		 • Results have been comprehensively reported in this
announcement.
• All drill holes completed, including holes with no significant
gold intersections, are reported.
Other exploration data, if meaningful and material,
should be reported including (but not limited to):
geological observations; geophysical survey results;
geochemical survey results; bulk samples – size and
method of treatment; metallurgical test results; bulk
density, groundwater, geotechnical and rock
characteristics; potential deleterious or
contaminating substances.		 • There is no other exploration data which is considered
material to the results reported in this announcement.
Further work The nature and scale of planned further work (e.g.
tests for lateral extensions or depth extensions or
large-scale step-out drilling).
Diagrams clearly highlighting the areas of possible
extensions, including the main geological
interpretations and future drilling areas, provided
this information is not commercially sensitive.		 • Further drilling is warranted to test for extensions of the
identified zones of mineralisation at Govisou, particularly at
depth.

35

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APPENDIX C – JORC TABLE 1 BAGOÉ PERMIT

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

Criteria JORC Code explanation Commentary
Sampling
techniques
Nature and quality of sampling (eg cut
channels, random chips, or specific
specialised industry standard measurement
tools appropriate to the minerals under
investigation, such as down hole gamma
sondes, or handheld XRF instruments, etc).
These examples should not be taken as
limiting the broad meaning of sampling.

Include reference to measures taken to
ensure sample representivity and the
appropriate calibration of any measurement
tools or systems used.

Aspects of the determination of
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.		 Air core drilling (AC) used a 105mm face-
sampling blade bit.
Reverse Circulation drilling (RC) used a
135mm face sampling hammer.
Samples from both AC and RC holes were
collected at 1m intervals.
Each sample was manually riffle split to
produce a subsample of approximately 3kg.
Drilling
techniques
Drill type (eg core, reverse circulation,
open-hole hammer, rotary air blast, auger,
Bangka, sonic, etc) and details (eg core
diameter, triple or standard tube, depth of
diamond tails, face-sampling bit or other
type, whether core is oriented and if so, by
_what method, etc). _		 Air core drilling (AC) used a 105mm face-
sampling blade bit.
Reverse Circulation drilling (RC) drilling used a
135mm face sampling hammer.
Drill sample
recovery
Method of recording and assessing core
and chip sample recoveries and results
assessed.

Measures taken to maximise sample
recovery and ensure representative nature
of the samples.

Whether a relationship exists between
sample recovery and grade and whether
sample bias may have occurred due to
preferential loss/gain of fine/coarse
material.		 Sample condition (dry, damp, wet) and a
qualitative description of sample quality (high,
moderate, low) were logged.
The weight of each entire recovered sample
was recorded.
Reject samples have been retained at site in
“sample farms”.
The relationship between sample recoveries
and gold grades has yet to be investigated.
Logging
Whether core and chip samples have been
geologically and geotechnically logged to a
level of detail to support appropriate
Mineral Resource estimation, mining
studies and metallurgical studies.

Whether logging is qualitative or
quantitative in nature. Core (or costean,
channel, etc) photography.

The total length and percentage of the		 All holes were field logged by Perseus
geologists. Weathering, oxidation, lithology,
alteration and veining information were
recorded.
Reference samples were stored in chip trays
and all chip trays photographed.
All drill holes were logged in full.

36

==> picture [114 x 35] intentionally omitted <==

Criteria JORC Code explanation Commentary
relevant intersections logged.
Sub-
sampling
techniques
and sample
preparation
If core, whether cut or sawn and whether
quarter, half or all core taken.

If non-core, whether riffled, tube sampled,
rotary split, etc and whether sampled wet or
dry.

For all sample types, the nature, quality and
appropriateness of the sample preparation
technique.

Quality control procedures adopted for all
sub-sampling stages to maximise
representivity of samples.

Measures taken to ensure that the
sampling is representative of the in situ
material collected, including for instance
results for field duplicate/second-half
sampling.

Whether sample sizes are appropriate to
the grain size of the material being
sampled.		 Each sample was manually riffle split to
produce a 2-3kg subsample.
Subsamples were transported to Perseus’s
sample preparation laboratory at Yaouré Gold
Mine where they were weighed as received,
dried, weighed after drying (to determine
moisture content), crushed to -2mm, then a
riffle split portion of approximately 1kg was
pulverised to approximately 90% passing 75
µm. The pulverised product was then dumped
on a rubber mat, rolled and approximately
300g selected by multiple dips of a spatula and
packaged in a kraft paper packet.
Sample grind size was monitored by screening
1:100 samples.
Duplicate field split samples were collected for
each 1:20 samples.
Duplicate pulp samples were created for each
1:20 samples.
Quality of
assay data
and
laboratory
tests
The nature, quality and appropriateness of
the assaying and laboratory procedures
used and whether the technique is
considered partial or total.

For geophysical tools, spectrometers,
handheld XRF instruments, etc, the
parameters used in determining the
analysis including instrument make and
model, reading times, calibrations factors
applied and their derivation, etc.

Nature of quality control procedures
adopted (eg standards, blanks, duplicates,
external laboratory checks) and whether
acceptable levels of accuracy (ie lack of
bias) andprecision have been established.		 Samples were assayed by Bureau Veritas
Abidjan using 50g fire assay with AAS finish for
gold only. The technique is considered a
measure of total gold.
Assay accuracy and reliability were monitored
by insertion of blanks at 1:20 samples and
reference standards (CRMs) at 1:20 samples.
The performances of blanks and standards
were monitored as assay results were
received.
The commercial laboratory’s internal QAQC
includes the use of certified reference materials
and pulp replicates.
Verification
of sampling
and
assaying
The verification of significant intersections
by either independent or alternative
company personnel.

The use of twinned holes.

Documentation of primary data, data entry
procedures, data verification, data storage
(physical and electronic) protocols.

Discuss any adjustment to assay data.		 Intervals of significant gold grades were
compared to logging of quartz veining,
alteration and mineralisation and chip tray
photographs.
Assays were plotted on cross-sections to check
that significant intercepts conform to the
expected locations of mineralisation and make
geometric sense.
Five diamond core holes have been drilled at
Véronique and six at Antoinette to twin RC
holes previously drilled by Exore Resources.
Assays from the twin holes are yet to be
received.
Hand-written records of sample intervals and
sample numbers, and geological and sample
quality logs are keyed into spreadsheet files
which are then imported into an aQuire®
database supervised by Perseus’s database
administrator.
Validation checks are undertaken to ensure
internal consistency of sample intervals and
logged hole depths and down-hole surveys are
sense checked.

37

==> picture [114 x 35] intentionally omitted <==

Criteria JORC Code explanation Commentary
Assay values that were below detection limit
(0.01g/t Au) were adjusted to equal half of the
detection limit value (0.005g/t Au).
Location of
data points
Accuracy and quality of surveys used to
locate drill holes (collar and down-hole
surveys), trenches, mine workings and
other locations used in Mineral Resource
estimation.

Specification of the grid system used.

Quality and adequacy of topographic
control.		 Ground surveys of drill hole collars are
presently incomplete. The locations provided
in the announcement derive from hand-held
GPS readings which are expected to be
reliable to +/- 2m in X-Y. Coordinates are
stated in WGS84 Zone 29N UTM grid.
All holes have been down-hole surveyed at
approximately 30 depth increments using a
Reflex digital compass instrument.
Drone photogrammetric surveys have recently
been undertaken over the Antoinette, Juliette
and Véronique areas but results are yet to be
received. An interim topographic surface has
been created using +/- 1m spot height data
from the Shuttle Radar Topography Mission at
approximately 30m x 30m spacing and drill
hole collars “pinned” to that surface.
Data spacing
and
distribution
Data spacing for reporting of Exploration
Results.

Whether the data spacing and distribution
is sufficient to establish the degree of
geological and grade continuity appropriate
for the Mineral Resource and Ore Reserve
estimation procedure(s) and classifications
applied.

Whether sample compositing has been
applied.		 Recent drilling at Véronique has infilled drill
spacing to nominal 20m x 20m in plan view.
The announcement does not include
information concerning resource estimates.
The question concerning sample compositing
is not relevant.
Orientation
of data in
relation to
geological
structure
Whether the orientation of sampling
achieves unbiased sampling of possible
structures and the extent to which this is
known, considering the deposit type.

If the relationship between the drilling
orientation and the orientation of key
mineralised structures is considered to
have introduced a sampling bias, this
should be assessed and reported if
material.		 Véronique mineralization strikes NW and dips
at approximately 45 degrees toward the SW.
In holes drilled at -60 degrees dip toward 045
degrees azimuth, true widths are approximately
equal to down-hole intercept lengths.
No orientation-based sampling bias has been
identified in the data.
Sample
security
The measures taken to ensure sample
security.		 Chain of custody was managed by Perseus.
Perseus employees retained custody of
subsamples from drill sites through transport to
the Yaouré sample preparation laboratory,
through that facility and then transport of
subsample pulps to the commercial laboratory
in Abidjan.
Audits or
reviews
The results of any audits or reviews of
sampling techniques and data.		 No independent review of sampling techniques
and data has been undertaken.

38

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Section 2 Reporting of Exploration Results

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

JORC 2012 Table 1 – Section 2 Reporting of Exploration Results

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

Criteria JORC Code explanation Commentary
Mineral
tenement and
land tenure
status
Type, reference name/number, location and
ownership including agreements or material
issues with third parties such as joint
ventures, partnerships, overriding royalties,
native title interests, historical sites,
wilderness or national park and environmental
settings.

The security of the tenure held at the time of
reporting along with any known impediments
to obtaining a license to operate in the area.		 Antoinette, Véronique and Juliette gold deposits form
part of the Bagoé Gold Project comprising Permit de
Recherche (PR) 321 covering 271.3 sq km. The permit
was granted 29 October 2014 and was recently renewed
for the first time to 28 October 2021. Further renewals
are permitted.
PR321 is held 100% by Aspire Nord Côte d’Ivoire sarl, a
wholly owned subsidiary of Perseus Mining Limited.
The Government of the Côte d’Ivoire retains the right to
take up 10% non-contributing beneficial ownership of
any portion of the PR that is converted to an exploitation
permit.
Exploration
done by other
parties
Acknowledgment and appraisal of exploration
by other parties.		 Previous exploration was carried out by Apollo
Consolidated Ltd from October 2014 to June 2018.
Exploration activities included soil sampling and auger,
air core, RC and diamond drilling.
Previous exploration was carried out by Exore
Resources Limited between July 2018 and July 2020.
Exploration activities included air core, RC and diamond
drilling.
Data arising from work by Apollo and Exore are
available to Perseus and are considered generally
reliable.
Geology
Deposit type, geological setting and style of
mineralisation.		 The Bagoé Gold Project is located in the West African
Craton and covers Palaeo-proterozoic (Birimian) rocks
of the southern extension of the Syama Greenstone Belt
and the western margin of the Senoufo Greenstone Belt.
Gold deposits at Bagoé are of the orogenic, greenstone-
hosted type and probably lie within the Senoufo belt.
Antoinette gold deposit is hosted by a fine-grained,
siliceous and, in places, carbonaceous metasediment
unit within a sequence of felsic volcaniclastic rocks and
porphyritic dioritic dykes. Mineralisation is subvertical,
extends over about 650m strike, with individual lenses
generally about 10m wide though in places lenses
combine to form widths of up to 25m. Weathering
extends to 50-60m depth.
Juliette gold deposit is located 3.5km SW of Antoinette
and is hosted by the extension of the Antoinette
sequence/structure.
Mineralisation
is subvertical,
extends over about 300m strike and generally comprises
a single lens 4-10m wide. Weathering extends to 30-40m
depth.
Véronique gold deposit is located 16km SSE of
Antoinette. Mineralisation extends over 900m strike and
s generally comprises a single NW-striking quartz vein 1-
2m thick that dips at 45 degrees to the SW. The vein is
hosted by an extensive granodiorite stock. Alteration
selvages extending 2-3m either side of the vein result, in
places, in 6-8m true thickness of mineralisation.
Weathering extends to 50-60m depth.
Drill hole
information
A summary of all information material to the
understanding of the exploration results
including a tabulation of the following		 A complete listing of results of all recent drill holes at
Véronique deposit is provided in the announcement.

39

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Criteria JORC Code explanation Commentary
information for all Material drill holes:

easting and northing of the drill hole collar

elevation or RL (Reduced Level – elevation
above sea level in metres) of the drill hole
collar

dip and azimuth of the hole

down hole length and interception depth

hole length

If the exclusion of this information is justified
on the basis that the information is not
Material and this exclusion does not detract
from the understanding of the report, the
Competent Person should clearly explain why
this is the case.		 The table includes hole locations, dips and azimuths and
total depths.
Details are not provided for other drill holes discussed in
the announcement, for which assays are not yet
available.
Data
aggregation
methods
In reporting Exploration Results, weighting
averaging techniques, maximum and/or
minimum grade truncations (e.g. 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.		 Significant intercepts are those exceeding 5g/t x metres
using a 0.5g/t cut-off, 2m maximum included waste and
no top cut.
Short lengths of high grade that materially affect
aggregate results are reported separately as “included”
intercepts.
Metal equivalents are not reported.
Relationship
between
mineralisation
widths and
intercept
lengths
These relationships are 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 should be reported.

If it is not known and only the down hole
lengths are reported, there should be a clear
statement to this effect (e.g.’down hole length,
_true width not known’). _		 Véronique mineralization dips at approximately 45
degrees. In holes drilled at -60 degrees dip, true widths
are approximately equal to down-hole intercept lengths.
Diagrams
Appropriate maps and sections (with scales)
and tabulations of intercepts should be
included for any significant discovery being
reported. These should include, but not be
limited to a plan view of drill hole collar
locations and appropriate sectional views.		 A drill hole location map and representative cross-
section are included in the announcement.
Balanced
Reporting
Accuracy and quality of surveys used to
locate drill holes (collar and down-hole
surveys), trenches, mine workings and other
locations used in Mineral Resource
estimation.

Where comprehensive reporting of all
Exploration Results is not practicable,
representative reporting of both low and high
grades and/or widths should be practiced to
avoid misleading reporting of Exploration
Results.		 Ground surveys of drill hole collars are presently
incomplete. The locations provided in the
announcement derive from hand-held GPS.
Coordinates are stated in WGS84 Zone 29N UTM grid.
A complete listing of results of all recent drill holes at
Véronique deposit, including those with no significant
intercepts, is provided in the announcement. Details are
not provided for other drilling discussed in the
announcement, for which assays are not yet available.
Other
substantive
exploration
data
Other exploration data, if meaningful and
material, should be reported including (but not
limited to): geological observations;
geophysical survey results; geochemical
survey results; bulk samples - size and
method of treatment; metallurgical test
results; bulk density, groundwater,
geotechnical and rock characteristics;
potential deleterious or contaminating
substances.		 The results of exploration by previous operators of the
Bagoé project have been the subject of announcements
by those operators.
Metallurgical test work by previous operator Exore
Resources Limited has confirmed that:

oxide and transition mineralisation at Antoinette is
amenable to gold extraction by cyanide leaching,
with gold recoveries of 94 to 97%.

Primary mineralization at Antoinette is partially
refractory, with preliminary test work indicating
cyanide leach gold recoveries of about 50%.

40

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Criteria JORC Code explanation Commentary

No cyanide leach tests have been undertaken on
Véronique oxide and transition mineralization.
Gold recoveries are expected to approximate 90%.

Cyanide leach tests on samples of Véronique
primary mineralization indicate gold recoveries of
88-90%.
No metallurgical test work has been undertaken on
Juliette mineralisation. Given the deposit’s similarity to
Antoinette, it is expected that primary mineralisation is
partially refractory.
There are no known deleterious or contaminating
substances associated with any of the deposits that
might imperil their exploitation.
Further work
The nature and scale of planned further work
(e.g. tests for lateral extensions or depth
extensions or large- scale step-out drilling).

Diagrams clearly highlighting the areas of
possible extensions, including the main
geological interpretations and future drilling
areas, provided this information is not
commercially sensitive.		 Perseus intends to use the results of drilling conducted
during the December 2020 quarter to update the
estimates of resources at Véronique and Antoinette
deposits and produce a maiden resource estimate for
the Juliette deposit.
Exploration by previous operators has located other
occurrences of gold mineralization within the Bagoé
Gold Project that Perseus intends to pursue.

41

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May 19
Transaction in Own Shares 2026
May 18
Transaction in Own Shares 2026
May 17
Transaction in Own Shares 2026
May 14
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