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RAND MINING LIMITED Interim / Quarterly Report 2021

Jan 21, 2021

65721_rns_2021-01-21_72824b3c-e6ed-424d-97a9-488c703b18d6.pdf

Interim / Quarterly Report

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ASX ANNOUNCEMENT

22 January 2021

EKJV Exploration Report December 2020 Quarter

ASX:RND

Board of Directors

Mr Otakar Demis Chairman & Joint Company Secretary

Mr Anton Billis Managing Director

Mr Gordon Sklenka Non-Executive Director

Mr Brett Tucker & Mr Roland Berzins Joint Company Secretaries Rand Mining Ltd (ASX code: RND) has pleasure in providing the Quarterly EKJV Exploration Report.

The EKJV is located 25km west north west of Kalgoorlie and 47km north east of Coolgardie. The EKJV is between Rand (12.25%), Tribune Resources Ltd (36.75%) and Northern Star Resources Ltd (51%).

This report has been released with the approval of the Board of Rand Mining Ltd.

-ENDS-

For further information, please contact: Brett Tucker Joint Company Secretary E: [email protected] Ph: + 61 8 9482 0500

For Media and Broker Enquiries

Peter Klinger Cannings Purple E: [email protected] Ph: + 61 411 251 540

EAST KUNDANA JOINT VENTURE

December 2020 Quarterly EKJV Exploration Report

For distribution to JV Partners:

  • Northern Star Resources Limited
  • Tribune Resources Limited
  • Rand Mining Limited

1 EXECUTIVE SUMMARY 4
2 EXPLORATION DRILLING 4
2.1 Surface Drilling 4
2.2 Underground Drilling 4
2.3 Golden Hind 6
3 GEOPHYSICS 9
3.1 High-Resolution Gravity Survey 9
4 EXPLORATION RESULTS 10
4.1 Falcon 10
4.2 Startrek 10
4.3 Pode 11
4.3.1 Underground 11
4.3.2 Surface 12
4.4 Hornet 13
4.4.1 Underground 13
4.4.2 Surface 13
4.5 Golden Hind 15
5 Future Work 16
5.1 In-Mine Exploration 16
6 APPENDIX 1 17
Table 1: EKJV exploration drilling activity for Q2 FY20/21 4
Table 2: Drilling physicals for the underground in-mine exploration across EKJV mining areasduring Q2 FY20/21 5
Table 3: Drilling physicals for the Golden Hind surface RC drilling program during Q2 FY20/21 . 7
Table 4: Summary of significant assay results returned for Falcon drilling during Q2 FY20/21 10
Table 5: Summary of significant assays results returned for Startrek drilling during Q2 FY20/21. 11
Table 6: Summary of significant assays results returned for Pode underground drilling during Q2FY20/21 12
Table 7: Summary of significant assays results returned for Pode surface drilling during Q2FY20/21 12
Table 9: Summary of significant assay results returned for Hornet surface drilling during Q2FY20/21 14
Table 10. Summary of significant assays results for Golden Hind. 15

Figure 2: Sectional overview of in-mine exploration drilling programs (drill traces in red) targetingthe Pode and Notus prospects during Q2 FY20/21 6
Figure 3: Plan view of Hornet showing underground drilling programs (drill traces in red)targeting the Hornet K2B and Startrek prospects during Q2 FY20/2 6
Figure 4. Location map of Golden Hind in relation to Raleigh and Rubicon open pits. 8
Figure 5. Golden Hind RC drilling collar positions within the area being evaluated as an openpit opportunity. 8
Figure 6: Plan showing results of recent high-resolution gravity survey. 9
Figure 5: Plan view of Falcon drilling and core photos from significant results in FALDT20039,FALDT20169, FALDT20044 and FALDT20161during Q2 FY20/2. 10
Figure 6: North looking cross sectional view and core photos of significant results returned forSTKRT20042 and STKRT20058. 11
Figure 7: North looking cross sectional view and core photos of significant results returned forPODRT20052, PODRT20053 and PODRT20054 during Q2 FY20/21 12
Figure 8: East looking long sectional view and core photos of significant results returned forPGDD20006 and PGDD20007 during Q2 FY20/21 13
Figure 9: North looking cross sectional view and core photos of significant results from Hornetsurface drilling program during Q2 FY20/21 14

1 EXECUTIVE SUMMARY

Exploration activity in the December 2020 quarter across the East Kundana Joint Venture focused on in-mine exploration of the Star Trek, Pode and Hornet Prospects.

Surface exploration consisted surface drilling at Hornet, Pode and Golden Hind and completion of a close-spaced gravity survey over the northern EKJV tenements.

Project Prospect Tenement RAB/ACMetres RAB/ACSamples RCMetres RCSamples DDMetres DDSamples MESamples
Surface Hornet M16/309 - - - - 2,750 2,809 -
Golden Hind M16/309 - - 4,113 4,318 4,113 4,318
Hornet M16/309 - - - - 2,954 3,124 -
Pode M16/309 - - - - 7,605 4,645 -
In-Mine Star Trek M16/309 - - - - 1,783 2,386 -
Pegasus M16/309 - - - - - 91 -
Total - - 4,113 4,318 15,092 13,055 -

Table 1: EKJV exploration drilling activity for Q2 FY20/21

2 EXPLORATION DRILLING

2.1 Surface Drilling

During the December quarter, a surface diamond drill rig continued the Hornet resource conversion and extension program targeting mineralisation in the footwall of the Centenary Main Vein (CMV) proximal to the Mary Fault. The rig demobilised on 24 November after completing eighteen holes and a further two metallurgical test work holes. Drill hole details for these programs are included under the Rubicon-Hornet-Pegasus-Falcon header (Table 2).

Figure 1: Overview of the Hornet surface exploration drilling program targeting mineralisation proximal to the Mary Fault zone drilled during Q2 FY20/21

2.2 Underground Drilling

A total of 38 underground diamond drill holes for 12,342 metres were completed during the quarter (Table 2). Underground exploration drilling from Pode platforms targeted the Startrek, Pode and Notus prospects (Figure 2), while drilling from the Hornet-Rubicon Link focused on Hornet K2B resource conversion and Hornet hanging wall lodes (Figure 3).

HoleID East(MGA) North(MGA) RL(MGA) HoleType Dip(deg) Azimuth(MGA) Depth(m)
HORDD20005 333945 6596699 339 DD -60 62 99.4
HORDD20006 333922 6596671 338 DD -59 59 117.41
HORDD20007 333887 6596652 339 DD -60 59 43.0
HORDD20007A 333887 6596651 339 DD -59 59 156.2
HORDD20008 333906 6596686 340 DD -60 64 144.18

Hole East North RL Hole Dip Azimuth Depth
ID (MGA) (MGA) (MGA) Type (deg) (MGA) (m)
HORDD20009 333955 6596730 340 DD -61 63 87.24
HORDD20010 333953 6596767 340 DD -59 84 83.7
HORDD20011 333907 6596762 341 DD -59 86 187.04
HORDD20012 333868 6596761 344 DD -59 88 231.42
HORDD20013 333932 6596826 340 DD -60 93 104.3
HORDD20014 333903 6596824 341 DD -61 85 147.5
HORDD20015 333864 6596821 344 DD -60 88 237.3
HORDD20016 333936 6596841 340 DD -60 79 80.0
HORDD20017 333916 6596855 340 DD -58 87 141.4
HORDD20018 333885 6596868 341 DD -57 92 204.48
HORDD20019 333864 6596883 343 DD -59 85 222.44
HORDD20020 333842 6596866 344 DD -60 86 270.21
HORDD20021 333840 6596915 344 DD -59 59 61.0
HORDD20022 333846 6596897 344 DD -62 60 81.1
HORDD20023 333934 6596803 341 DD -58 56 51.25
HORRT20028 333540 6597271 183 DD -11 280 104.92
HORRT20029 333541 6597269 186 DD 37 212 107.59
HORRT20040 333812 6596902 186 DD -6 217 251.84
HORRT20041 333812 6596902 186 DD -3 194 345.43
HORRT20042 333812 6596902 186 DD 5 178 437.0
HORRT20043 333812 6596902 186 DD -13 204 405.2
HORRT20044 333812 6596902 186 DD -5 187 357.49
HORRT20045 333704 6597014 152 DD 35 265 200.68
HORRT20046 333705 6597014 151 DD 11 247 14.83
HORRT20047 333705 6597014 150 DD -17 230 327.36
HORRT20049 333705 6597014 150 DD -19 195 402.2
PODRT20206 332849 6597920 12 DD -8 46 156.0
PODRT20207 332849 6597920 12 DD -25 55 163.52
PODRT20208 332849 6597920 12 DD -42 40 158.48
PODRT20210 332849 6597920 12 DD -31 71 179.98
PODRT20211 332849 6597920 11 DD -55 36 185.97
PODRT20212 332849 6597920 11 DD -46 61 174.1
PODRT20346 332712 6598483 -111 DD 22 310 348.0
PODRT20348 332713 6598485 -110 DD 21 319 455.66
PODRT20349 332712 6598484 -112 DD 8 309 387.49
PODRT20350 332712 6598484 -112 DD -10 297 525.1
PODRT20351 332712 6598484 -112 DD -6 307 489.07
PODRT20359 332712 6598484 -112 DD -8 310 354.2
PODRT20360 332712 6598484 -112 DD -19 304 390.25
PODRT20361 332712 6598484 -112 DD -8 318 390.4
PODRT20362 332712 6598484 -112 DD -17 312 426.21
PODRT20373 332930 6598268 221 DD -4 231 242.79
PODRT20374 332931 6598267 222 DD 11 232 209.78
PODRT20375 332712 6598483 -111 DD 26 316 353.7
PODRT20377 332712 6598483 -111 DD 14 306 363.04
PODRT20378 332712 6598484 -112 DD 14 311 390.0
PODRT20380 332712 6598483 -111 DD 4 305 456.44
PODRT20383 332712 6598483 -111 DD -6 293 515.35
PODRT20395 332712 6598483 -111 DD 27 307 287.97
STKRT20058 333488 6597500 76 DD 9 16 447.28
STKRT20078 333545 6597273 183 DD -17 45 459.3
STKRT20079 333545 6597273 183 DD -23 67 456.0
STKRT20080 333545 6597273 183 DD -44 56 420.07

Table 2: Drilling physicals for the underground in-mine exploration across EKJV mining areas during Q2 FY20/21

Figure 2: Sectional overview of in-mine exploration drilling programs (drill traces in red) targeting the Pode and Notus prospects during Q2 FY20/21.

Figure 3: Plan view of Hornet showing underground drilling programs (drill traces in red) targeting the Hornet K2B and Startrek prospects during Q2 FY20/2.

2.3 Golden Hind

The Golden Hind prospect is located on the Strzelecki structure south from the Raleigh mine (Figure 4).

A program of infill surface RC drilling encompassing 59 holes was completed during the quarter providing a nominal 40m by 40m drill spacing coverage over a potential shallow open pit area (Table 3)(Figure 5).

Hole East North RL Hole Dip Azimuth Depth
ID (MGA) (MGA) (MGA) Type (deg) (MGA) (m)
GHRC20015 332651 6597206 342 RC -60 062 150
GHRC20016 332686 6597226 342 RC -60 062 118
GHRC20017 332721 6597245 342 RC -60 062 84
GHRC20018 332756 6597265 342 RC -60 062 48
GHRC20019 332706 6597191 342 RC -60 062 120
GHRC20020 332741 6597210 342 RC -60 062 84
GHRC20021 332775 6597230 342 RC -60 062 42
GHRC20022 332810 6597249 342 RC -60 062 12
GHRC20023 332705 6597146 342 RC -60 062 130
GHRC20024 332740 6597166 342 RC -60 062 96
GHRC20025 332775 6597185 342 RC -60 062 66

Hole East North RL Hole Dip Azimuth Depth
ID (MGA) (MGA) (MGA) Type (deg) (MGA) (m)
GHRC20026 332809 6597206 342 RC -60 062 30
GHRC20027 332724 6597111 342 RC -60 062 126
GHRC20028 332759 6597131 342 RC -60 062 96
GHRC20029 332794 6597150 342 RC -60 062 60
GHRC20030 332829 6597170 342 RC -60 062 30
GHRC20031 332864 6597189 342 RC -60 062 18
GHRC20032 332732 6597068 342 RC -60 062 144
GHRC20033 332767 6597087 342 RC -60 062 102
GHRC20034 332802 6597107 342 RC -60 062 72
GHRC20035 332842 6597131 342 RC -60 062 30
GHRC20036 332877 6597150 342 RC -60 062 18
GHRC20037 332745 6597029 342 RC -60 062 138
GHRC20038 332780 6597049 342 RC -60 062 114
GHRC20039 332773 6597000 342 RC -60 062 126
GHRC20040 332808 6597020 342 RC -60 062 90
GHRC20041 332843 6597039 342 RC -60 062 60
GHRC20042 332875 6597059 342 RC -60 062 30
GHRC20043 332910 6597077 342 RC -60 062 24
GHRC20044 332774 6596955 342 RC -60 062 144
GHRC20045 332809 6596974 342 RC -60 062 114
GHRC20046 332844 6596994 342 RC -60 062 72
GHRC20047 332883 6597015 342 RC -60 062 36
GHRC20048 332918 6597034 342 RC -60 062 12
GHRC20049 332787 6596913 342 RC -60 062 144
GHRC20050 332822 6596933 342 RC -60 062 108
GHRC20051 332857 6596952 342 RC -60 062 66
GHRC20052 332895 6596975 342 RC -60 062 36
GHRC20053 332930 6596994 342 RC -60 062 12
GHRC20054 332819 6596886 342 RC -60 062 114
GHRC20055 332854 6596905 342 RC -60 062 84
GHRC20056 332846 6596854 342 RC -60 062 114
GHRC20057 332880 6596874 342 RC -60 062 60
GHRC20058 332916 6596895 342 RC -60 062 36
GHRC20059 332951 6596914 342 RC -60 062 12
GHRC20060 332857 6596819 342 RC -60 062 73
GHRC20061 332892 6596839 342 RC -60 062 60
GHRC20062 332929 6596857 342 RC -60 062 24
GHRC20063 332964 6596877 342 RC -60 062 12
GHRC20064 332869 6596778 342 RC -60 062 114
GHRC20065 332904 6596798 342 RC -60 062 72
GHRC20066 332940 6596819 342 RC -60 062 24
GHRC20067 332975 6596839 342 RC -60 062 12
GHRC20068 332948 6596776 342 RC -60 062 36
GHRC20069 332965 6596786 342 RC -60 062 18
GHRC20070 332887 6596719 342 RC -60 062 114
GHRC20071 332923 6596738 341 RC -60 062 78
GHRC20072 332958 6596757 341 RC -60 062 36
GHRC20073 332976 6596766 341 RC -60 062 18

Table 3: Drilling physicals for the Golden Hind surface RC drilling program during Q2 FY20/21

Figure 4. Location map of Golden Hind in relation to Raleigh and Rubicon open pits.

Figure 5. Golden Hind RC drilling collar positions within the area being evaluated as an open-pit opportunity.

3 GEOPHYSICS

3.1 High-Resolution Gravity Survey

A high-resolution survey was completed north of the Kundana tenements covering M16/181, M16/182 and M16/325 tenements. This dataset will help interpret the structural-stratigraphic architecture around the Zuleika Shear and assist targeting gold mineralisation on secondary or tertiary structures with future drilling programs (Figure 6).

Figure 6: Plan showing results of recent high-resolution gravity survey.

4 EXPLORATION RESULTS

4.1 Falcon

Seven Falcon diamond holes returned significant intersection results during the quarter. Most significant intersections were in holes south of the current extent of the Falcon orebody, drilled from Rubicon.

HoleID East(MGA) North(MGA) RL(AHD) Dip(deg) Azi(MGA) HoleDepth(m) From(m) To(m) DHWidth(m) Gradeg/t Au TrueWidth(m)
FALDT20044 333243 6597624 -19 -22 267 411.17 297.93 298.59 0.66 3.5 0.5
317 317.3 0.3 15.5 0.2
FALDT20161 333214 6597377 -323 -33 258 336.12 39.88 40.68 0.8 3.7 0.5
70.3 70.7 0.4 2.1 0.3
73.6 76.75 3.15 2.0 2.1
123.65 124.3 0.65 3.1 0.4
FALDT20079 333243 6597624 -18 -5 267 336.22 Results pending
FALRT20039 332759 6598367 -97 -5 267 360.34 38.95 39.49 0.54 2.3 0.5
45.65 46.14 0.49 2.6 0.4
FALRT20150 331985 6598955 147 18 032 324.07 237.35 237.74 0.39 5.4 0.3
FALRT20151 331985 6598955 148 19 041 309.0 Results pending
FALRT20152 331985 6598954 147 19 058 306.0 228.9 229.25 0.35 7.1 0.3
FALRT20165 331846 6598480 -283 -15 063 522.4 Results pending
FALRT20168 331846 6598480 -282 5 081 564.54 Results pending
FALRT20169 331846 6598480 -282 -7 088 618.43 533.0 533.5 0.5 2.2 0.4
537.21 539.05 1.84 5.9 1.6
FALRT20170 331846 6598480 -283 -15 084 554.2 67.6 68.0 0.4 2.8 0.4
474.63 475.19 0.56 2.3 0.5

Table 4: Summary of significant assay results returned for Falcon drilling during Q2 FY20/21

Figure 7: Plan view of Falcon drilling and core photos from significant results in FALDT20039, FALDT20169, FALDT20044 and FALDT20161during Q2 FY20/2.

4.2 Startrek

Two diamond drill holes targeting Startrek returned significant intersections during the quarter. Mineralisation grading greater than 10 g/t was seen in narrow, irregular quartz veins within the footwall volcanic sediment package.

HoleID East(MGA) North(MGA) RL(AHD) Dip(deg) Azi(MGA) HoleDepth(m) From(m) To(m) DHWidth(m) Gradeg/t Au TrueWidth(m)
STKRT20042 333394 6597626 -62 20 075 422.66 41.0 41.46 0.46 2.9 0.4
47.0 47.36 0.36 3.2 0.3
62.97 63.41 0.44 3.6 0.4
238.85 240.07 1.22 39.1 1.0
STKRT20043 333394 6597626 -62 10 075 404.0 Results Pending
STKRT20058 333488 6597500 76 9 016 447.28 1.0 1.42 0.42 2.3 0.2

EKJV Quarterly Report – December 2020 Page 10

195.4 195.92 0.52 69.4 0.3
255.16 255.49 0.33 136.0 0.2
STKRT20078 333545 6597273 183 -17 045 459.3 Results Pending
STKRT20079 333545 6597273 183 -23 067 456.0 Results Pending
STKRT20080 333545 6597273 183 -44 056 420.07 Results Pending

Table 5: Summary of significant assays results returned for Startrek drilling during Q2 FY20/21

Figure 8: North looking cross sectional view and core photos of significant results returned for STKRT20042 and STKRT20058.

4.3 Pode

4.3.1 Underground

Three diamond drill holes targeting the Pode structure returned significant intersections during the quarter. While all holes intersected the target structure, there is considerable geological variability with PODRT20052 intersecting a strongly sheared zone and PODRT20054 intersecting a narrow, laminated quartz vein.

HoleID East(MGA) North(MGA) RL(AHD) Dip(deg) Azi(MGA) HoleDepth(m) From(m) To(m) DHWidth(m) Gradeg/t Au TrueWidth(m)
PODRT20052 333108 6598017 -186 1 204 254.03 178.75 179.21 0.46 2.6 0.4
225.0 225.81 0.81 51.4 0.7
242.0 243.0 1.0 3.6 0.8
PODRT20053 333107 6598020 -184 38 208 158.68 95.0 95.37 0.37 4.1 0.3
123.6 124.0 0.4 11.2 0.3
139.41 142.67 3.26 2.5 2.9
144.7 146.87 2.17 2.0 1.9
PODRT20054 333108 6598018 -185 20 194 239.76 142.26 143.0 0.74 9.2 0.5
153.0 154.0 1.0 3.1 0.7
158.16 158.6 0.44 3.7 0.3
176.0 185.5 9.5 4.3 6.6
PODRT20206 332849 6597920 12 -8 046 156.0 Results Pending
PODRT20207 332849 6597920 12 -25 055 163.52 Results Pending
PODRT20208 332849 6597920 12 -42 040 158.48 Results Pending
PODRT20210 332849 6597920 12 -31 071 179.98 Results Pending
PODRT20211 332849 6597920 11 -55 036 185.97 Results Pending
PODRT20212 332849 6597920 11 -46 061 174.1 Results Pending
PODRT20346 332712 6598483 -111 22 310 348.0 Results Pending
PODRT20347 343240 6595512 -110 6 327 297.47 Results Pending
PODRT20348 332713 6598485 -110 21 319 455.66 Results Pending
PODRT20349 332712 6598484 -112 8 309 387.49 Results Pending
PODRT20350 332712 6598484 -112 -10 297 525.1 Results Pending
PODRT20351 332712 6598484 -112 -6 307 489.07 Results Pending
PODRT20359 332712 6598484 -112 -8 310 354.2 Results Pending
PODRT20360 332712 6598484 -112 -19 304 390.25 Results Pending
PODRT20361 332712 6598484 -112 -8 318 390.4 Results Pending
PODRT20362 332712 6598484 -112 -17 312 426.21 Results Pending

HoleID East(MGA) North(MGA) RL(AHD) Dip(deg) Azi(MGA) HoleDepth(m) From(m) To(m) DHWidth(m) Gradeg/t Au TrueWidth(m)
PODRT20373 332930 6598268 221 -4 231 242.79 Results Pending
PODRT20374 332931 6598267 222 11 232 209.78 Results Pending
PODRT20375 332712 6598483 -111 26 316 353.7 Results Pending
PODRT20377 332712 6598483 -111 14 306 363.04 Results Pending
PODRT20378 332712 6598484 -112 14 311 390.0 Results Pending
PODRT20380 332712 6598483 -111 4 305 456.44 Results Pending
PODRT20383 332712 6598483 -111 -6 293 515.35 Results Pending
PODRT20395 332712 6598483 -111 27 307 287.97 Results Pending

Table 6: Summary of significant assays results returned for Pode underground drilling during Q2 FY20/21

Figure 9: North looking cross sectional view and core photos of significant results returned for PODRT20052, PODRT20053 and PODRT20054 during Q2 FY20/21

4.3.2 Surface

Three diamond drill holes targeting northern extensions of Pode from surface returned significant intersections during the quarter. While all holes intersected the target structure, there is considerable geological variability, with PGDD20006 intersecting a narrow, laminated vein and PGDD20007 intersecting wider zones of irregular veining.

HoleID East(MGA) North(MGA) RL(AHD) Dip(deg) Azi(MGA) HoleDepth(m) From(m) To(m) DHWidth(m) Gradeg/t Au TrueWidth(m)
PGDD20004 332549 6598665 344 -61 071 256.34 233.65 233.83 0.18 3.7 0.1
PGDD20005 332507 6598655 344 -62 073 400.0 Results pending
PGDD20006 332456 6598633 344 -62 070 411.36 297.65 298.04 0.39 3.5 0.1
311.0 311.65 0.65 2.3 0.2
PGDD20007 332472 6598706 344 -63 074 372.27 137.0 137.4 0.4 4.0 0.1
278.92 283.0 4.08 3.7 1.3
286.2 287.2 1.0 4.2 0.3
291.72 292.07 0.35 4.2 0.1

Table 7: Summary of significant assays results returned for Pode surface drilling during Q2 FY20/21

Figure 10: East looking long sectional view and core photos of significant results returned for PGDD20006 and PGDD20007 during Q2 FY20/21

4.4 Hornet

4.4.1 Underground

All assay results for the 11 underground diamond drill holes into Hornet hanging wall targets are still pending.

4.4.2 Surface

Seven surface diamond drill holes targeting the upper CMV at Hornet returned significant intersections during the quarter (Table 8 and Figure 8). All holes intersected the target zone with additional mineralisation in both the weathered portions of the footwall and hangingwall.

HoleID East(MGA) North(MGA) RL(AHD) Dip(deg) Azi(MGA) HoleDepth(m) From(m) To(m) DHWidth(m) Gradeg/t Au TrueWidth(m)
HORDD20001 333943 6596635 337 -60 058 96.5 39.5 41.1 1.6 11.6 1.1
HORDD20002 333926 6596617 337 -59 058 129.57 NSI
HORDD20003 333906 6596605 337 -60 059 168.52 40.3 41.1 0.8 4.1 0.5
73.3 73.7 0.4 10.0 0.2
EKJVMANAGEMENT PTY LTD
79.5 80.4 0.9 14.3 0.5
82.9 83.52 0.62 2.1 0.3
HORDD20005 333945 6596699 339 -60 062 99.4 Results Pending
HORDD20006 333922 6596671 338 -59 059 117.41 Results Pending
HORDD20007 333887 6596652 339 -60 059 43.0 Results Pending
HORDD20007A 333887 6596651 339 -59 059 156.2 Results Pending
HORDD20008 333906 6596686 340 -60 064 144.18 Results Pending
HORDD20009 333955 6596730 340 -61 063 87.24 Results Pending
HORDD20010 333953 6596767 340 -59 084 83.7 29.0 29.4 0.4 16.7 0.3
34.4 34.7 0.3 2.7 0.3
HORDD20011 333907 6596762 341 -59 086 187.04 93.5 93.8 0.3 3.2 0.2
95.93 98.99 3.06 2.6 1.9
129.37 130.18 0.81 27.9 0.5
133.0 134.29 1.29 2.1 0.8
HORDD20012 333868 6596761 344 -59 088 231.42 Results Pending
HORDD20013 333932 6596826 340 -60 093 104.3 31.55 32.43 0.88 27.2 0.8
HORDD20014 333903 6596824 341 -61 085 147.5 56.91 57.25 0.34 6.0 0.2
130.2 130.5 0.3 3.5 0.2
146 146.39 0.39 3.2 0.2
HORDD20015 333864 6596821 344 -60 088 237.3 Results Pending
HORDD20016 333936 6596841 340 -60 079 80.0 11.8 12.0 0.2 10.8 0.1
56.0 56.4 0.4 3.4 0.3
66.4 66.75 0.35 3.1 0.2
HORDD20017 333916 6596855 340 -58 087 141.4 Results Pending
HORDD20018 333885 6596868 341 -57 092 204.48 Results Pending
HORDD20019 333864 6596883 343 -59 085 222.44 Results Pending
HORDD20020 333842 6596866 344 -60 086 270.21 Results Pending
HORDD20021 333840 6596915 344 -59 059 61.0 Results Pending
HORDD20022 333846 6596897 344 -62 060 81.1 Results Pending
HORDD20023 333934 6596803 341 -58 056 51.25 Results Pending

Table 8: Summary of significant assay results returned for Hornet surface drilling during Q2 FY20/21

Figure 11: North looking cross sectional view and core photos of significant results from Hornet surface drilling program during Q2 FY20/21

4.5 Golden Hind

Results from 48 holes of the surface RC drilling completed at Golden Hind were received by the end of the quarter with results from the remaining eleven holes still outstanding (Table 9).

Hole DH True
Hole ID East(MGA) North(MGA) RL(AHD) Dip(deg) Azi(MGA) Depth From(m) To(m) Width Gradeg/t Au Width
(m) (m) (m)
GHRC20015 332647 6597207 341 -58 62 150 142 143 1 1.79 0.8
GHRC20016 332686 6597228 342 -59 60 118 106 108 2 15.71 1.6
GHRC20017 332718 6597242 343 -59 59 84 76 78 2 0.30 1.6
GHRC20018 332754 6597262 343 -57 58 48 39 41 2 0.32 1.6
GHRC20019 332704 6597190 342 -59 60 120 106 107 1 0.54 0.8
GHRC20020 332741 6597211 342 -56 64 84 66 67 1 2.40 0.8
GHRC20021 332776 6597230 343 -59 63 42 32 33 1 1.59 0.8
GHRC20022 332809 6597248 343 -59 59 12 NSI
GHRC20023GHRC20024 332702332742 65971466597166 342343 -58-59 5764 13096 12183 12384 21 10.109.12 1.60.8
GHRC20025 332778 6597187 343 -56 62 66 48 51 3 12.50 2.4
GHRC20026 332811 6597210 343 -60 62 30 15 24 9 3.41 7.2
GHRC20027 332721 6597111 343 -60 62 126 120 121 1 2.53 0.8
GHRC20028 332761 6597133 343 -59 61 96 83 84 1 9.15 0.8
GHRC20029 332794 6597151 343 -56 63 60 49 50 1 1.12 0.8
GHRC20030 332827 6597169 343 -57 56 30 13 14 1 1.16 0.8
GHRC20031 332863 6597188 343 -61 57 18 NSI
GHRC20032 332732 6597069 342 -59 60 144 126 128 2 0.60 1.6
GHRC20033 332765 6597087 342 -58 63 102 NSI
GHRC20034 332801 6597108 343 -57 62 72 58 61 3 8.40 2.4
GHRC20035 332842 6597131 343 -58 60 30 14 16 2 5.81 1.6
GHRC20036 332874 6597148 343 -60 62 18 NSI
GHRC20037 332742 6597031 341 -58 67 138 130 131 1 0.96 0.8
GHRC20038 332780 6597049 342 -60 62 114 Results Pending
GHRC20039 332773 6597000 341 -60 62 126 Results Pending
GHRC20040 332811 6597021 342 -59 64 90 Results Pending
GHRC20041 332842 6597039 343 -59 63 60 51 52 1 0.88 0.8
GHRC20042 332876 6597060 343 -58 63 30 18 23 5 0.57 3.2
GHRC20043 332908 6597078 343 -61 64 24 NSI
GHRC20044 332773 6596958 341 -60 62 144 Results Pending
GHRC20045 332801 6596971 341 -58 62 114 96 97 1 2.72 0.8
GHRC20046GHRC20047 332844332887 65969956597016 342342 -58-58 6365 7236 5822 6023 21 0.651.55 1.60.8
GHRC20048 332928 6597038 343 -59 61 12 NSI
GHRC20049 332787 6596915 341 -60 62 144 Results Pending
GHRC20050 332821 6596934 342 -62 55 108 90 92 2 3.80 1.6
GHRC20051 332855 6596957 342 -58 57 66 54 57 3 0.62 2.4
GHRC20052 332892 6596974 343 -58 60 36 16 19 3 2.10 2.4
GHRC20053 332927 6596994 343 -59 63 12 NSI
GHRC20054 332820 6596887 341 -59 59 114 102 103 1 0.63 0.8
GHRC20055 332857 6596907 342 -58 58 84 64 66 2 12.36 1.6
GHRC20056 332846 6596856 342 -60 60 114 87 89 2 0.25 1.6
GHRC20057 332882 6596876 342 -60 62 60 49 51 2 0.30 1.6
GHRC20058 332916 6596895 343 -58 65 36 12 16 4 1.36 3.2
GHRC20059 332952 6596914 343 -59 63 12 NSI
GHRC20060 332855 6596819 341 -60 60 73 NSI
GHRC20061 332889 6596837 342 -58 62 60 52 53 1 7.03 0.8
GHRC20062 332929 6596860 343 -59 60 24 7 9 2 1.71 1.6
GHRC20063 332960 6596875 343 -59 61 12 NSI
GHRC20064 332865 6596778 345 -57 61 114 93 94 1 0.39 0.8
GHRC20065GHRC20066 332898332939 65967966596819 345345 -59-60 6761 7224 558 619 61 1.005.52 4.80.8
GHRC20067 332975 6596840 345 -60 59 12 NSI
GHRC20068 332949 6596775 343 -60 62 36
GHRC20069 332967 6596783 343 -60 62 18
GHRC20070 332888 6596721 342 -60 62 114
GHRC20071 332923 6596738 342 -60 62 78 Results Pending
GHRC20072 332959 6596756 343 -60 62 36
GHRC20073 332976 6596766 343 -60 62 18

Table 9. Summary of significant assays results for Golden Hind.

5 Future Work

5.1 In-Mine Exploration

Exploration drilling will continue to test the northern extents of the Pode orebody and southern extents of Hera during the next quarter.

Infill drilling at Startrek will continue to reduce the spacing between positive intersections to the east of Rubicon.

The return of the final eleven holes' assay results will allow for interpretation and evaluation of the Golden Hind project.

Competency Statement

The information in this report relating to Exploration Results is based on information compiled by Dr Rick Gordon who is a Member of the Australian Institute of Geoscientists and has sufficient exploration experience which is relevant to the style of mineralisation under consideration 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'. Dr Gordon is a full-time employee of Northern Star Resource Limited and consents to the inclusion in the report of the matters based on his information in the form and context in which it appears.

6 APPENDIX 1

JORC Code, 2012 Edition – Table 1

Section 1 Sampling Techniques and Data

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

Criteria JORC Code Explanation Commentary
Sampling techniques  Nature and quality of sampling (e.g. cut channels, random chips, orspecific specialised industry standard measurement tools appropriate tothe minerals under investigation, such as down hole gamma sondes, orhandheld XRF instruments, etc.). These examples should not be taken aslimiting the broad meaning of sampling. Include reference to measures taken to ensure sample representivityand the appropriate calibration of any measurement tools or systemsused. Aspects of the determination of mineralisation that are Material to thePublic Report. In cases where 'industry standard' work has been done this would berelatively simple (e.g. 'reverse circulation drilling was used to obtain 1 msamples from which 3 kg was pulverised to produce a 30g charge for fireassay'). In other cases, more explanation may be required, such aswhere there is coarse gold that has inherent sampling problems. Unusualcommodities or mineralisation types (e.g. submarine nodules) maywarrant disclosure of detailed information.  Sampling was completed using combination of Reverse Circulation (RC) and diamond drill core(DD). RC samples were split using a rig-mounted cone splitter on 1m intervals to obtain a sample for assay.These 1m samples were submitted for assay within 24 hours. Diamond core was transferred to core trays for logging and sampling. Half core or full core sampleswere nominated by the geologist from HQ or NQ diamond core, with a minimum sample width of20cm and a maximum width of 120cm. Samples were transported to various analysis laboratories in Kalgoorlie for preparation by drying,crushing to <3mm, and pulverizing the entire sample to <75μm. 300g Pulp splits were analysed in laboratories in both Kalgoorlie and Perth for 40-50g Fire assaycharge and AAS analysis for gold.
Drilling techniques  Drill type (e.g. core, reverse circulation, open-hole hammer, rotary airblast, auger, Bangka, sonic, etc.) and details (e.g. core diameter, tripleor standard tube, depth of diamond tails, face-sampling bit or othertype, whether core is oriented and if so, by what method, etc.).  For underground drilling, NQ2 (50.6mm) diameter core was used. Core was orientated using an electronic 'back-end tool' core orientation system. RC Drilling was completed using a 5.75" drill bit, downsized to 5.25" at depth.
Drill sample recovery  Method of recording and assessing core and chip sample recoveriesand results assessed. Measures taken to maximise sample recovery and ensure representativenature of the samples. Whether a relationship exists between sample recovery and grade andwhether sample bias may have occurred due to preferential loss/gainof fine/coarse material.  Moisture content and sample recovery are recorded for each RC sample. For diamond drilling the contractors adjust their rate of drilling and method if recovery issues arise.All recovery is recorded by the drillers on core blocks. This is checked and compared to themeasurements of the core by the geological team. Any issues are communicated back to thedrilling contractor. RC drilling contractors adjust their drilling approach to specific conditions to maximize samplerecovery. Moisture content and sample recovery are recorded for each RC sample. No recoveryissues were identified during 2020 RC drilling. Recovery was poor at the very beginning of each hole,as is normal for this type of drilling in overburden. Recovery was excellent for diamond core and no relationship between grade and recovery wasobserved.

Criteria JORC Code Explanation Commentary
Logging  Whether core and chip samples have been geologically andgeotechnically logged to a level of detail to support appropriate MineralResource estimation, mining studies and metallurgical studies.  All diamond core is logged for regolith, lithology, veining, alteration, mineralisation and structure.Structural measurements of specific features are taken through oriented zones. All logging isquantitative where possible and qualitative elsewhere. A photograph is taken of every core tray.
 Whether logging is qualitative or quantitative in nature. Core (orcostean, channel, etc.) photography.  RC sample chips are logged in 1m intervals. For the entire length of each hole. Regolith, Primarylithology, alteration, veining and mineralisation are all recorded.
 The total length and percentage of the relevant intersections logged.
Sub-sampling techniques and  If core, whether cut or sawn and whether quarter, half or all core taken.  All diamond core that was half-core sampled was cut longitudinally with an automated core saw.
sample preparation  If non-core, whether riffled, tube sampled, rotary split, etc. and whethersampled wet or dry.  All RC samples are split using a rig-mounted cone splitter to collect a 1m sample 3-4kg in size.Moisture content of the sample is recorded and noted if wet samples are obtained.
 For all sample types, the nature, quality and appropriateness of thesample preparation technique.  Sample preparation was conducted at various laboratories in Kalgoorlie, commencing with sorting,checking and drying at less than 110°C to prevent sulphide breakdown. Samples are jaw crushed
 Quality control procedures adopted for all sub-sampling stages tomaximise representivity of samples. to a nominal -6mm particle size. The entire crushed sample is then pulverized to 90% passing 75μm,using a bowl or ring-mill pulveriser. 300g Pulp subsamples are then taken with an aluminium scoopand stored in labelled pulp packets.
 Measures taken to ensure that the sampling is representative of the insitu material collected, including for instance results for fieldduplicate/second-half sampling.  Grind checks are performed at both the crushing stage (3mm) and pulverising stage (75μm),requiring 90% of material to pass through the relevant size to ensure consistent sample preparation.
 Whether sample sizes are appropriate to the grain size of the materialbeing sampled.
Quality of assay data andlaboratory tests  The nature, quality and appropriateness of the assaying and laboratoryprocedures used and whether the technique is considered partial ortotal.  A 40-50g fire assay charge is used with a lead flux, dissolved in the furnace. The prill is totally digestedin HCl and HNO3 acids before Atomic Absorption Spectroscopy (AAS) determination for goldanalysis. This method ensures total gold is reported appropriately.
 For geophysical tools, spectrometers, handheld XRF instruments, etc., the  No geophysical tools were used to determine any element concentrations.
parameters used in determining the analysis including instrument makeand model, reading times, calibrations factors applied and theirderivation, etc.  Certified Reference Materials (CRMs) are inserted into the sample sequence randomly at a rate of1 per 20 composite samples to ensure correct calibration. Any values outside of 3 standarddeviations are scrutinised and re-assayed with a new CRM if the failure is deemed genuine.
 Nature of quality control procedures adopted (e.g. standards, blanks,duplicates, external laboratory checks) and whether acceptable levelsof accuracy (i.e. lack of bias) and precision have been established.  Blanks are inserted into the sample sequence at a rate of 1 per 20 composite samples. Failures above0.2g/t are scrutinised and re-assayed if required. New pulps are prepared if failures remain.
 All sample QAQC results are assessed by geologists to ensure the appropriate level of accuracy andprecision when the results have been returned from the laboratory.
 Field duplicates are taken for all RC samples (1 in 50 samples)
Verification of sampling andassaying  The verification of significant intersections by either independent oralternative company personnel.  All significant intersections are verified by the project geologist and senior geologist during the drillhole validation process.
 The use of twinned holes.  No holes were twinned as part of the programmes in this report.
 Documentation of primary data, data entry procedures, dataverification, data storage (physical and electronic) protocols.  Geological logging was captured using Acquire database software. Assay files are received in csvformat and loaded directly into the database by the supervising geologist who then checks that theresults have inserted correctly. Hardcopy and electronic copies of these are also kept. No
 Discuss any adjustment to assay data. adjustments are made to this assay data.

Criteria JORC Code Explanation Commentary
Location of data points  Accuracy and quality of surveys used to locate drill holes (collar anddown-hole surveys), trenches, mine workings and other locations used inMineral Resource estimation. Specification of the grid system used. Quality and adequacy of topographic control.  All collars for underground drilling are located in the local mine grid by a mine surveyor using a lasertheodolite. A planned surface diamond or RC hole is pegged using a hand-held GPS by the geologist. The finalcollar is picked up after hole completion by Differential GPS in the MGA 94 Zone 51 grid. Duringdrilling, single-shot surveys are taken every 30m as a minimum standard to ensure the hole remainsclose to design with a further survey taken at the end of hole. A continuous north-seeking gyro toolis used. A more detailed survey (i.e. more survey stations) is generally conducted upon completionof the hole. Results are uploaded to an online server, where they can be downloaded and importedinto Northern Star's Acquire database.
Data spacing and distribution  Data spacing for reporting of Exploration Results. Whether the data spacing and distribution is sufficient to establish thedegree of geological and grade continuity appropriate for the MineralResource and Ore Reserve estimation procedure(s) and classificationsapplied. Whether sample compositing has been applied.  Surface drillhole spacing is variable and dependent on the interpreted geometries of geology andmineralisation at individual prospects. In-mine diamond drillholes spacings are also variable from 80m apart through to isolated singledrillholes. Closer spaced drilling is considered operational drilling, beyond the scope of this report.
Orientation of data in relationto geological structure  Whether the orientation of sampling achieves unbiased sampling ofpossible structures and the extent to which this is known, considering thedeposit type. If the relationship between the drilling orientation and the orientation ofkey mineralised structures is considered to have introduced a samplingbias, this should be assessed and reported if material.  All drilling both underground and surface is oriented as close as practical to perpendicular to thetarget structures. The orientation of all in-mine target structures is well known and drill holes are onlydesigned where meaningful intersect angles can be achieved. No sampling bias is considered to have been introduced by the drilling orientation.
Sample security  The measures taken to ensure sample security.  Prior to laboratory submission samples are stored by Northern Star in a secure yard. Once submittedto the laboratories they are stored in a secure fenced compound and tracked through their chainof custody via audit trails.
Audits or reviews  The results of any audits or reviews of sampling techniques and data.  No audits or reviews have recently been conducted on sampling techniques; however, lab auditsare conducted on a regular basis.

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 landtenure status  Type, reference name/number, location and ownership includingagreements 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.  All diamond holes mentioned in this report are located within the M16/309 and M15/993 Miningleases held by The East Kundana Joint Venture (EKJV). The EKJV is majority owned and managed byNorthern Star Resources Ltd (51%). The minority holding in the EKJV is held by Tribune Resources Ltd(36.75%) and Rand Mining Ltd (12.25%).
 The security of the tenure held at the time of reporting along with anyknown impediments to obtaining a licence to operate in the area.  M16/309 is subject to two royalty agreements; however, neither of these is applicable to theProspects described in this report. The agreements concerned are the Kundana‐ Hornet CentralRoyalty and the Kundana Pope John Agreement No. 2602‐13. No known impediments exist and thetenement is in good standing
Exploration done by otherparties  Acknowledgment and appraisal of exploration by other parties.  Underground drilling on the Raleigh and Hornet-Rubicon-Pegasus mines extends the mineralisedtrends from older drilling including that of previous operators of those mines including Barrick Gold,Placer Dome Asia-Pacific, Aurion Gold, Goldfields Limited and other predecessors.
Geology  Deposit type, geological setting and style of mineralisation.  The Kundana camp is situated within the Norseman-Wiluna Greenstone Belt, in an area dominatedby the Zuleika Shear Zone, which separates the Coolgardie domain from the Ora Banda domain.The Zuleika Shear Zone in the Kundana area comprises multiple anastomosing shears the mostimportant of which are the K2, the K2A and Strzelecki Shears. Raleigh and Golden Hind mineralisation are hosted on the Strzelecki Structure. Strzeleckimineralisation consists of very narrow, very high-grade mineralisation on a laminated vein hosted inthe camp-scale Strzelecki Shear which abuts a differentiated mafic intrusive, the Powder SillGabbro against intermediate volcanoclastic rocks (Black Flag Group). A thin 'skin' ofvolcanogenic lithic siltstone-sandstone lies between the gabbro and the Strzelecki shear. Beingbound by an intrusive contact on one side and a sheared contact on the other, the thickness ofthe sedimentary package is highly variable from absent to about forty metres true width. The Hornet-Rubicon-Pegasus mineralisation consists primarily of high-grade laminated vein hostedgold on the K2 plane of the Zuleika shear with additional mineralisation on associated lower-orderstructures. The Falcon target is a related mineralised zone in the hangingwall to Pegasus andbetween the two main Zuleika structures, the K2 and Strzelecki structures.
Drill hole Information  A summary of all information material to the understanding of theexploration results including a tabulation of the following information forall material drill holes: easting and northing of the drill hole collar elevation or RL (Reduced Level – elevation above sea level inmetres) of the drill hole collar dip and azimuth of the hole down hole length and intersection depth hole length. If the exclusion of this information is justified on the basis that theinformation is not Material and this exclusion does not detract from theunderstanding of the report, the Competent Person should clearlyexplain why this is the case.  Refer to the various tables in the body of this report. Exploration results that are not material to this report are excluded for some drill programmes,however, the drill physicals are all detailed for all drilling regardless of the outcome.

Criteria JORC Code Explanation Commentary
Data aggregation methods  In reporting Exploration Results, weighting averaging techniques,maximum and/or minimum grade truncations (e.g. cutting of highgrades) and cut-off grades are usually Material and should be stated.  All drill results are reported as aggregates across the target zone.
 Where aggregate intersects incorporate short lengths of high-graderesults and longer lengths of low-grade results, the procedure used forsuch aggregation should be stated and some typical examples of suchaggregations should be shown in detail.
 The assumptions used for any reporting of metal equivalent valuesshould be clearly stated.
Relationship betweenmineralisation widths and  These relationships are particularly important in the reporting ofExploration Results.  The orientation of target structures is well known for all in-mine exploration targets and true widthscan be accurately calculated and are reported accordingly.
intersect lengths  If the geometry of the mineralisation with respect to the drill hole angleis known, its nature should be reported.  Both the downhole width and true width have been clearly specified when used.
 If it is not known and only the down hole lengths are reported, thereshould be a clear statement to this effect (e.g. 'down hole length, truewidth not known').
Diagrams  Appropriate maps and sections (with scales) and tabulations ofintersects should be included for any significant discovery beingreported. These should include, but not be limited to a plan view of drillhole collar locations and appropriate sectional views.  Refer to the figures the body of this report for the spatial context of all holes planned and drilled todate.
Balanced reporting  Where comprehensive reporting of all Exploration Results is notpracticable, representative reporting of both low and high gradesand/or widths should be practised to avoid misleading reporting ofExploration Results.  Exploration results that are not material to this report are excluded for some drill programmes,however, the drill physicals are all detailed for all drilling regardless of the outcome.
Other substantive explorationdata  Other exploration data, if meaningful and material, should be reportedincluding (but not limited to): geological observations; geophysicalsurvey results; geochemical survey results; bulk samples – size andmethod of treatment; metallurgical test results; bulk density,groundwater, geotechnical and rock characteristics; potentialdeleterious or contaminating substances.  No other material exploration data has been collected for this drill program.
Further work  The nature and scale of planned further work (e.g. tests for lateralextensions or depth extensions or large-scale step-out drilling).  Further planned work is referenced in the report body
 Diagrams clearly highlighting the areas of possible extensions, includingthe main geological interpretations and future drilling areas, providedthis information is not commercially sensitive.

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