Novo Resources Corp. (Novo or the Company) (ASX: NVO) (TSX: NVO) (OTCQX: NSRPF) is pleased to advise that a Determination Wide Aboriginal Heritage Protection Agreement (the Agreement) has been signed between Novo and the Nyamal Aboriginal Corporation (NAC). The execution of this Agreement streamlines the interactions between Novo and the Nyamal People and confirms Novo’s commitment to open, honest and transparent dealings with the Traditional Owners of the Pilbara Region.

The Agreement with NAC covers a large part of the East Pilbara District and allows Novo to conduct non ground disturbing surface works including mapping and surface geochemistry, specifically targeting the priority Bamboo and Miralga Projects. A cultural heritage site avoidance survey took place at Bamboo on 6 and 7 August 2024 to enable drill testing, with a final report expected later in the month.

The Agreement also provides for compensation payments for the benefit of the Traditional Owners which are customary and in line with normal commercial terms for similar agreements of this nature.

EAST PILBARA DISTRICT

The East Pilbara District encompasses Novo tenements around the townships of Marble Bar and Nullagine (Figure 1) and fall within the Nyamal and Palyku Native Title Determination areas.

Approximately 1,500 sq km of prospective and under explored tenure around Marble Bar is currently being advanced by mapping, geochemical surveys and geophysical/remote sensing interpretation. The large landholding comprises orogenic and intrusion-related gold targets, including porphyry / intermediate sulphidation epithermal-style targets at Gully Washer and Shady Camp West on the Miralga Project. A new target style now includes a series of sanukitoid-like intrusions which are evident along a major structural corridor trending along the Nullagine and Bamboo / Strattons projects. Unusual wire gold has been identified in proximity to one of these intrusions at Strattons.

Figure 1: East Pilbara District

Bamboo – Strattons

The Bamboo and Strattons Projects are located approximately 60 km east of Marble Bar. Regional exploration programs completed by Novo and previous explorers, have identified several gold anomalous zones within the Apex Basalt of the Warrawoona Group. The Apex Basalt is the host to orogenic gold prospects along strike, including the Bamboo Creek mining centre (Figure 2), where total historical production is estimated to be over 220,000 ounces at 8.7 g/t Au2.

Figure 2: Bamboo - Strattons Projects showing mapped or interpreted intrusion targets

The tenure contains a series of 1.77 Ga Bridget Suite intrusions as part of a 150 km north-northwest trend (Figure 2). Soil sampling completed by Novo has returned anomalous gold results in proximity to multiple intrusions some of which are emplaced into the otherwise unmineralised Upper Fortescue sequences, suggesting mineralisation is related to their emplacement. During field work – surface gold (Figure 3) was detected in the form of wire gold in proximity to one of these intrusions.

The Bridget Suite intrusions range in composition from hornblende monzogranite to quartz monzonite and associated hornblende porphyry dykes; and as such they postdate the Archean orogenic mineralisation events associated with gold deposits in the Mosquito Creek and Mallina Basins.

_____________________________________

2 Refer to the Calidus Resources Ltd (ASX: CAI) ASX news release dated 19 February 2024 available at www.asx.com.au. Novo has not conducted data verification (including as that term is defined in National Instrument 43-101 Standards of Disclosure for Mineral Projects) in respect of the data/information set out in that news release under the JORC Code 2012 or NI 43-101.

With the new Nyamal Agreement now in place, Novo intends to conduct detailed mapping and soil sampling over 2 km strike of the Apex Basalt and two Bridget Suite intrusions to identify drill targets for RC drill testing.

Figure 3: Photos of fine native gold with an unusual wire-like habit, found in proximity to an intrusion at Bamboo.

Cautionary Statement: Visual occurrence of surface gold cannot be taken as representative of bedrock mineralisation and no assaying of the occurrence has been undertaken. Visual estimates of mineral abundance should never be considered a proxy or substitute for laboratory analyses where concentrations or grades are the factor of principal economic interest. Visual estimates also potentially provide no information regarding impurities or deleterious physical properties relevant to valuations.

Miralga Project

The Miralga Project is located 30 km west of Marble Bar. The project is located on the eastern flank of the North Pole Dome where exploration in the 1970s and 1990s focussed on porphyry-style and epithermal vein-style mineralisation within the Panorama Formation. Known porphyry mineralisation is present outside of Novo’s tenure at Miralga Creek B (Figure 4), where Au-Ag-Cu mineralisation is associated with a stock-like Archaean porphyry, high-level dykes and epithermal veins.

Geophysical and remote sensing interpretation, coupled with review of existing geochemical datasets, identified several porphyry targets on Novo’s tenure where some targets have seen little to no historical exploration. Anomalies were defined using airborne magnetics and radiometric surveys (particularly potassium anomalies), sentinel and satellite imagery, along with normalising base metal geochemical data from the 1970s to 1990s. Porphyry and intrusion-related targets have now been defined over 25 km strike (Figure 4).

Three targets were investigated in the field, two of which require significant follow-up – Gully Washer and Shady Camp West.

Gully Washer is a precious and base-metal rich breccia and vein array related to a felsic porphyry stock which outcrops over 275 m and is up to 35 m width (Figure 5). Rock samples collected by Novo in 2021 returned peak results of 14.8 g/t Au, 10,083 g/t Ag (342 oz/t Ag), 3.8% Cu, 28.3% Pb and 3.6% Zn3 (results are not necessarily representative of mineralisation in the district).

High-grade mineralisation is located along the flanks of the gossanous porphyry and related to a maximum six-metre-wide zone of malachite-bearing breccia on both hangingwall and footwall positions of the intrusion (Figure 6). The footwall of the mineralised gossanous outcrop returned four > 2,000 g/t Ag rock chip samples along 100 m of strike, including one sample of over 1 % Ag.

_____________________________________

3 Refer to Appendix 1 for assay results.

Exploration by Novo has included a handheld Niton XRF soil grid and reconnaissance mapping which defined intense alteration zones overlapping a 1 km long NW trending Cu soil anomaly (Figure 5). The Gully Washer breccia is centered in the approximate middle of the broader Cu anomaly and alteration zone.

Immediately east of Gully Washer, stream sediment sampling has yielded a peak assay of 266 ppb Au in an area with distinct color anomalism on airborne imagery (Figure 5).

Figure 4: Miralga Project showing mapped or interpreted intrusion targets

Additional mapping, alteration studies, and surface soil and rock chip sampling is planned for Q3 2024 to better delineate high grade mineralisation defined to date, to close off existing soil anomalism, to follow-up the highly anomalous stream sediment sample and to understand the scope of the broader intrusion related target.

Figure 5: Gully Washer prospect map showing rock sample results.

Figure 6: Mineralised gossan on the southern porphyry margin looking east. Sample R00988 (taken at the position of the central front sample bag) returned assays of 4.6 ppm Au, 99 ppm Ag, and 1.4% Pb4.

_____________________________________

4 Refer to Appendix 1 for assay results

Shady Camp West was defined in the 1980s, with broad surface mapping, rock chip sampling and costeaning defining Cu-Au-(Mo) enriched porphyry and intense alteration of the porphyry and adjacent host basalt (AMAX Australia 1980, 1981). Information disclosed in annual exploration reports filed by AMAX Australia Limited in 19825 that are available on the Western Australian Department of Energy, Mines, Industry Regulation and Safety’s (“DEMIRS”) website (WAMEX Reports), indicate that best costean sampling results include 30 m @ 631 ppm Cu and 100 m @ 461 ppm Cu, with peak assays of 1,350 ppm Cu and 0.32 g/t Au in an altered and potentially leached porphyry. Rock chip results included maximum values of 1.3 g/t Au and 12.5% Cu associated with the northern and southern margins of the rhyodacite intrusive (AMAX Australia 1980, 1981). Information disclosed in the WAMEX Reports will assist Novo with exploration targeting.

Cautionary Statement: The exploration results contained in the WAMEX Reports have not been reported in accordance with the JORC Code or NI 43-101 and a Competent Person/Qualified Person has not done sufficient work to disclose the exploration results in accordance with the JORC Code 2012 or NI 43-101. It is possible that following further evaluation and/or exploration work that the confidence in the prior reported exploration results may be reduced when reported under the JORC Code 2012 or NI 43-101. Novo confirms that nothing has come to its attention that causes it to question the accuracy or reliability of the results included in the WAMEX Reports, but Novo has not independently validated those results and therefore is not to be regarded as reporting, adopting or endorsing those results. No assurance can be given that Novo will achieve similar results as part of its exploration activities at Shady Camp West.

Shady Camp West was prioritised by Novo for investigation due to a large radiometric potassium anomaly extending over 2.2 km north to south (Figure 7) and discrete magnetic lows and highs associated with an intense colour anomaly on airborne imagery.

Work undertaken by Novo includes rock chip sampling, grid pXRF soil sampling and reconnaissance mapping. Geological mapping identified a suite of felsic porphyries intruding mafic and intermediate volcanics. Intense alteration and associated weathering products include kaolinitic clay and limonite, with silicification around quartz vein stockworks.

Indicative results from handheld Niton XRF soil sampling on 160 m x 40 m spaced E-W lines highlighted a >100 ppm coherent Cu anomaly over 1.2 km long, and open to the north, coincident with potassium alteration, magnetic complexity and maximum quartz veining (Figure 7).

The pXRF readings are not verified by an independent laboratory and are not considered to be a proxy or substitute for laboratory analysis. A single orientation line of -80# soil samples which were analysed by an independent laboratory has defined a weak Au and Mo anomaly correlating with pXRF Cu anomalies, with peak results of 26 ppb Au, 3.7 ppm Mo, 100 ppm As, 250 ppm Cu and 130 ppm Zn6. Results may not be representative of mineralisation in the district.

Novo intends to conduct detailed alteration and vein mapping, soil sampling and follow-up ground geophysics if warranted, to generate multi-element geochemistry data and geophysical anomalies to determine whether porphyry style mineralisation exists. This program will be conducted over several weeks in Q3 2024.

_____________________________________

5 Refer to Amax Australia Limited 1982 Shady Camp Well Prospect Final Report – WAMEX Open File Data Report A11565.6 Refer to Appendix 1 for assay results.

Figure 7: Shady Camp West highlighting geophysical anomalies (left) and pXRF soil Cu geochemical anomalies (right). The potassic anomaly over 2.2 km strike partially overlaps with intense clay alteration of porphyries and host basalt (light colouration on the imagery). Coherent Cu anomalism is open and untested to the north and correlates with maximum quartz veining and weak Au and Mo anomalism in soils.

ANALYTIC METHODOLOGY

Rock chip samples of 1 – 3 kg were submitted to Intertek commercial Genalysis (“Intertek”) in Perth, Western Australia where they were dried and crushed to -3 mm and pulverized to 75 µm or better (prep code SP64), with a > 85% pass, then assayed for Au by 50 g charge fire assay FA50/OE and for 48 elements using four acid digest – MS finish (4A/MS). Elements that reported above the upper detection limit for 4A/MS were reanalysed using method 4AH/OE. A minimum of 2 CRM standards relevant for the style of mineralisation and 2 blanks were submitted per 100 samples.

Soil samples were sieved to < 80 mesh and submitted to Intertek for aqua regia to analyse for 33 elements. A minimum of 2 CRM standards, 2 blanks and 4 field duplicates were submitted per 100 samples.

Stream sediment samples were sieved to < 0.9 mm and submitted to Intertek where they were dried and pulverized to 75 µm or better (prep code SP02), with a > 85% pass, then analysed for aqua regia for 33 elements. In addition, the samples are analysed via BLEG (Bulk Leach Extractable Gold) 500 g cyanide leach with MS finish for Au, Pt, Pd and Ag.

pXRF readings of soils and rock chips were taken using a Niton XLT5 model and were used to aid field interpretation and identification of anomalous target mineralogy and pathfinder elements. The Niton pXRF instrument was calibrated daily and checked against reference material four times per 100 samples and at the start and end of each day.

The Niton pXRF uses an x-ray fluorescence tube to take an immediate reading over a small surface area. It is used to obtain an indicative value of certain elements to assist with exploration targeting. The pXRF readings are not verified by an independent laboratory, are not considered to be a proxy or substitute for laboratory analysis. Results may not be representative of mineralisation in the district.

Except as otherwise noted in this news release, there were no limitations to the verification process and all relevant data was verified by a qualified person/competent person (as defined in National Instrument 43-101 Standards of Disclosure for Mineral Projects (NI 43-101) and the Australasian Code for Reporting of Exploration Results, Mineral Resources and Ore Reserves (JORC 2012, Appendix 2) respectively), by reviewing QAQC performance of inserted reference material and the analytical procedures undertaken by Intertek.

Authorised for release by the Board of Directors.

CONTACT

Investors:Mike Spreadborough +61 8 6400 6100 info@novoresources.com North American Queries:Leo Karabelas+1 416 543 3120leo@novoresources.com Media:Cameron Gilenko+61 466 984 953cameron.gilenko@sodali.com  

QP STATEMENT

Mrs Karen (Kas) De Luca (MAIG), is the qualified person, as defined under NI 43-101 Standards of Disclosure for Mineral Projects, responsible for, and having reviewed and approved, the technical information contained in this news release. Mrs De Luca is Novo’s General Manager Exploration.

JORC COMPLIANCE STATEMENT

The information in this report that relates to exploration results in the East Pilbara District is based on information compiled by Mrs De Luca, who is a full-time employee of Novo Resources Corp. Mrs De Luca is a Competent Person who is a member of the Australian Institute of Geoscientists. Mrs De Luca has sufficient experience that is relevant to the style of mineralisation and the type of deposits under consideration and to the activity being undertaken to qualify as a Competent Person as defined in the 2012 Edition of the 'Australasian Code for Reporting of Exploration Results, Mineral Resources and Ore Reserves'. Mrs De Luca consents to the inclusion in the report of the matters based on her information in the form and context in which it appears.

FORWARD-LOOKING STATEMENTS

Some statements in this news release may contain “forward-looking statements” within the meaning of Canadian and Australian securities law and regulations. In this news release, such statements include but are not limited to planned exploration activities and the timing of such. These statements address future events and conditions and, as such, involve known and unknown risks, uncertainties and other factors which may cause the actual results, performance or achievements to be materially different from any future results, performance or achievements expressed or implied by the statements. Such factors include, without limitation, customary risks of the resource industry and the risk factors identified in Novo’s annual information form for the year ended December 31, 2023 (which is available under Novo’s profile on SEDAR+ at www.sedarplus.ca and at www.asx.com.au) in the Company’s prospectus dated 2 August 2023 which is available at www.asx.com.au. Forward-looking statements speak only as of the date those statements are made. Except as required by applicable law, Novo assumes no obligation to update or to publicly announce the results of any change to any forward-looking statement contained or incorporated by reference herein to reflect actual results, future events or developments, changes in assumptions or changes in other factors affecting the forward-looking statements. If Novo updates any forward-looking statement(s), no inference should be drawn that the Company will make additional updates with respect to those or other forward-looking statements.

ABOUT NOVO

Novo is an Australian based gold explorer listed on the ASX and the TSX focused on discovering standalone gold projects with > 1 Moz development potential. Novo is an innovative gold explorer with a significant land package covering approximately 6,700 square kilometres in the Pilbara region of Western Australia, along with the 22 square kilometre Belltopper project in the Bendigo Tectonic Zone of Victoria, Australia.

Novo’s key project area is the Egina Gold Camp, where De Grey Mining (ASX: DEG) is farming-in to form a JV at the Becher Project and surrounding tenements through exploration expenditure of A$25 million within 4 years for a 50% interest. The Becher Project has similar geological characteristics as De Grey’s 12.7 Moz Hemi Project1. Novo is also advancing gold exploration at Nunyerry North, part of the Croydon JV (Novo 70%: Creasy Group 30%), where 2023 exploration drilling identified significant gold mineralisation. Novo continues to undertake early-stage exploration across its Pilbara tenement portfolio.

Novo has also formed lithium joint ventures with both Liatam and SQM in the Pilbara which provides shareholder exposure to battery metals.

Novo has a significant investment portfolio and a disciplined program in place to identify value accretive opportunities that will build further value for shareholders.

Please refer to Novo’s website for further information including the latest Corporate Presentation.

Appendix 1

Surface sample results for the Miralga Project, listing elements relevant to this mineralisation style(All sample locations are GPS located on MGA_2020 zone 50.)

Sample ID Type Prospect Au (ppm) Ag (ppm) Cu (ppm) Pb (ppm) Zn (ppm) Sb (ppm) Easting Northing
NX1361301 Rock Chip Gully Washer 14.81 64 3,588 10,965 36,416 1,161 757,548 7,665,836
NX1361302 Rock Chip Gully Washer 1.18 125 1,692 64,918 5,504 118 757,537 7,665,839
NX1361303 Rock Chip Gully Washer 0.08 2 86 461 611 11 757,564 7,665,985
NX1361304 Rock Chip Gully Washer 0.01 3 124 768 365 11 757,523 7,665,895
NX1361305 Rock Chip Gully Washer 0.01 2 117 70 120 12 757,522 7,665,884
NX1361306 Rock Chip Gully Washer 0.03 4 159 129 968 12 757,520 7,665,843
NX1361307 Rock Chip Gully Washer 2.34 40 3,464 9,508 10,334 352 757,522 7,665,839
NX1361308 Rock Chip Gully Washer 0.13 19 366 9,870 23,730 45 757,600 7,665,876
NX1361309 Rock Chip Gully Washer 0.02 1 32 203 423 15 757,606 7,665,885
NX1361311 Rock Chip Gully Washer 0.07 131 575 596 11,812 62 757,635 7,665,874
NX1361312 Rock Chip Gully Washer 3.60 2,130 14,857 9,008 1,258 1,123 757,635 7,665,878
NX1361313 Rock Chip Gully Washer 4.02 2,409 37,718 10,857 2,241 1,474 757,636 7,665,880
NX1361314 Rock Chip Gully Washer 6.07 2,013 33,529 5,138 4,970 2,480 757,638 7,665,882
NX1361315 Rock Chip Gully Washer 0.64 173 1,659 1,995 2,437 248 757,637 7,665,884
NX1361316 Rock Chip Gully Washer 0.48 34 376 1,714 6,389 30 757,657 7,665,881
NX1361317 Rock Chip Gully Washer 2.36 88 1,517 5,158 8,653 285 757,662 7,665,881
NX1361318 Rock Chip Gully Washer 4.23 177 5,691 14,239 10,653 1,384 757,676 7,665,878
NX1361319 Rock Chip Gully Washer 0.05 188 350 6,439 702 71 757,706 7,665,879
NX1361320 Rock Chip Gully Washer 0.04 51 103 2,083 1,839 79 757,703 7,665,877
NX1361321 Rock Chip Gully Washer 0.26 28 850 2,651 5,314 151 757,699 7,665,876
NX1361322 Rock Chip Gully Washer 0.01 3 37 235 489 14 757,720 7,665,877
NX1361325 Rock Chip Gully Washer 2.85 10,083 334 283,103 287 1,774 757,726 7,665,861
NX1361326 Rock Chip Gully Washer 0.74 48 220 4,525 554 138 757,756 7,665,859
NX1361327 Rock Chip Gully Washer 0.30 130 501 2,863 1,827 413 757,667 7,665,849
NX1361328 Rock Chip Gully Washer 0.04 12 454 6,575 5,159 12 757,468 7,665,887
NX1361329 Rock Chip Gully Washer 0.01 3 122 138 181 7 757,484 7,665,888
R00986 Rock Chip Gully Washer 0.64 22 827 13,110 2,035 45 757,633 7,665,852
R00987 Rock Chip Gully Washer 0.03 7 444 1,745 2,649 10 757,630 7,665,847
R00988 Rock Chip Gully Washer 4.55 99 325 14,262 538 481 757,625 7,665,850
R00989 Rock Chip Gully Washer 0.24 20 102 3,012 122 81 757,626 7,665,851
R00990 Rock Chip Gully Washer 0.13 10 451 3,383 6,745 81 757,610 7,665,851
R00991 Rock Chip Gully Washer 0.03 5 172 1,783 3,002 15 757,607 7,665,852
R00992 Rock Chip Gully Washer 1.96 10 549 2,786 3,868 155 757,608 7,665,855
R00993 Rock Chip Gully Washer 0.07 9 150 754 1,631 22 757,594 7,665,853
R00994 Rock Chip Gully Washer 0.05 14 111 431 1,370 42 757,594 7,665,851
R00995 Rock Chip Gully Washer 0.05 14 168 1,906 4,004 40 757,594 7,665,851
R00996 Rock Chip Gully Washer 0.05 7 238 2,421 3,974 26 757,596 7,665,846
R00997 Rock Chip Gully Washer 0.35 51 303 3,789 1,918 406 757,584 7,665,839
R00998 Rock Chip Gully Washer 0.06 30 60 6,225 255 92 757,581 7,665,843
R00999 Rock Chip Gully Washer 0.09 19 70 1,516 349 43 757,561 7,665,838
R01000 Rock Chip Gully Washer 0.87 96 186 3,413 432 658 757,559 7,665,837
Sample ID Type Project Au (ppb) Ag (ppm) Cu (ppm) Pb (ppm) Zn (ppm) Mo (ppm) Easting Northing
NVO-16206 Stream Miralga 2.0 0.05 65 7 70 0.3 764,097 7,662,491
NVO-16207 Stream Miralga 0.5 0.03 54 5 53 0.4 764,115 7,662,484
NVO-16208 Stream Miralga 2.0 0.06 73 7 84 0.7 764,154 7,662,359
NVO-16209 Stream Miralga 2.0 0.03 72 6 79 0.5 764,254 7,662,245
NVO-16210 Stream Miralga 2.0 0.03 69 5 82 0.5 764,259 7,662,234
NVO-16224 Stream Miralga 1.0 0.03 59 6 66 0.3 764,071 7,662,120
NVO-16225 Stream Miralga 1.0 0.03 70 5 88 0.5 764,094 7,662,104
NVO-16226 Stream Miralga 1.0 0.03 84 5 95 0.5 764,262 7,661,635
NVO-16227 Stream Miralga 1.0 0.03 70 6 87 0.3 764,234 7,661,276
NVO-16228 Stream Miralga 1.0 0.03 67 5 77 0.4 764,252 7,661,274
NVO-16229 Stream Miralga 0.5 0.06 55 12 74 0.7 764,379 7,661,143
NVO-16230 Stream Miralga 1.0 0.03 51 6 67 0.6 764,911 7,662,250
NVO-16231 Stream Miralga 2.0 0.03 46 6 67 0.6 764,995 7,662,439
NVO-16232 Stream Miralga 1.0 0.03 72 6 113 0.5 764,811 7,662,748
NVO-16233 Stream Miralga 0.5 0.03 60 6 92 0.5 764,798 7,662,770
NVO-16234 Stream Miralga 2.0 0.03 51 5 76 0.4 765,342 7,662,705
NVO-16235 Stream Miralga 2.0 0.03 70 5 80 0.4 765,363 7,662,585
NVO-16236 Stream Miralga 1.0 0.03 73 6 71 0.5 765,408 7,662,391
NVO-16237 Stream Miralga 0.5 0.03 102 13 101 0.5 765,419 7,662,052
NVO-16238 Stream Miralga 0.7 0.03 65 10 69 0.5 765,375 7,662,044
NVO-16240 Stream Miralga 1.0 0.03 66 6 85 0.7 765,198 7,662,795
NVO-16241 Stream Miralga 0.5 0.03 12 4 24 0.4 765,300 7,661,905
NVO-16242 Stream Miralga 0.5 0.03 19 4 42 0.5 765,161 7,661,801
NVO-16243 Stream Miralga 0.5 0.03 32 7 45 0.5 764,990 7,661,305
NVO-16244 Stream Miralga 0.5 0.03 47 9 63 0.7 764,854 7,661,227
NVO-16246 Stream Miralga 1.0 0.03 65 6 68 0.6 764,595 7,661,315
NVO-16247 Stream Miralga 0.5 0.03 129 4 101 0.3 759,709 7,661,134
NVO-16248 Stream Miralga 0.5 0.03 122 4 98 0.3 759,703 7,661,120
NVO-16249 Stream Miralga 688.4 0.03 118 6 72 0.3 759,571 7,661,257
NVO-16250 Stream Miralga 0.5 0.03 130 4 98 0.3 759,558 7,661,247
NVO-16276 Stream Miralga 0.5 0.03 119 6 114 0.3 759,438 7,661,238
NVO-16277 Stream Miralga 2.0 0.09 67 25 108 0.6 759,627 7,661,535
NVO-16278 Stream Miralga 2.0 0.05 73 29 128 0.4 759,631 7,661,516
NVO-16279 Stream Miralga 0.5 0.03 65 7 76 0.4 759,841 7,662,980
NVO-16280 Stream Miralga 1.0 0.05 61 7 81 0.4 759,704 7,662,924
NVO-16281 Stream Miralga 0.5 0.06 89 11 91 0.6 759,543 7,662,915
NVO-16282 Stream Miralga 0.5 0.03 50 9 129 0.4 759,554 7,662,891
NVO-16283 Stream Miralga 0.5 0.03 32 7 46 0.5 759,517 7,662,816
NVO-16284 Stream Miralga 0.5 0.03 65 8 72 0.5 759,599 7,663,809
NVO-16286 Stream Miralga 0.5 0.03 53 7 61 0.6 759,609 7,663,813
NVO-16287 Stream Miralga 0.5 0.03 25 9 58 0.7 759,520 7,663,530
NVO-16288 Stream Miralga 0.5 0.07 22 15 63 0.8 759,505 7,663,533
NVO-16289 Stream Miralga 0.5 0.06 64 11 94 0.4 759,108 7,662,227
NVO-16290 Stream Miralga 0.5 0.08 131 9 79 0.6 759,261 7,662,463
NVO-16291 Stream Miralga 0.5 0.03 67 20 136 1.0 758,070 7,663,986
NVO-16292 Stream Miralga 0.5 0.03 13 7 38 0.5 758,354 7,664,405
NVO-16293 Stream Miralga 0.5 0.06 86 26 107 0.6 758,352 7,664,332
NVO-16294 Stream Miralga 0.5 0.03 40 13 50 0.5 758,381 7,664,305
NVO-16296 Stream Miralga 0.5 0.03 58 15 128 0.4 758,455 7,664,248
NVO-16297 Stream Miralga 2.0 0.03 42 23 102 0.5 758,469 7,663,862
NVO-16298 Stream Miralga 0.5 0.08 91 25 163 0.9 758,271 7,663,688
NVO-16299 Stream Miralga 0.5 0.10 102 9 146 0.7 758,182 7,663,624
NVO-16354 Stream Miralga 0.5 0.13 17 62 77 0.5 758,411 7,664,874
NVO-16355 Stream Miralga 0.5 0.03 16 6 37 0.4 758,152 7,665,077
NVO-16356 Stream Miralga 0.5 0.03 21 7 48 0.6 758,083 7,665,062
NVO-16357 Stream Miralga 1.0 0.17 58 36 121 0.9 758,177 7,665,521
NVO-16358 Stream Miralga 12.0 1.12 64 128 153 0.8 758,197 7,665,623
NVO-16359 Stream Miralga 1.0 0.03 28 12 81 0.9 758,429 7,665,634
NVO-16360 Stream Miralga 0.5 0.03 15 9 69 0.7 758,417 7,665,636
NVO-16361 Stream Miralga 266.3 0.26 52 48 107 0.8 758,237 7,665,789
NVO-16362 Stream Miralga 0.8 0.08 108 14 131 0.6 756,641 7,667,321
NVO-16363 Stream Miralga 1.0 0.15 62 33 136 0.5 756,586 7,667,275
NVO-16364 Stream Miralga 0.5 0.16 89 23 154 0.5 757,129 7,666,582
NVO-16366 Stream Miralga 1.0 0.12 88 17 125 0.6 757,609 7,667,072
NVO-16367 Stream Miralga 0.5 0.15 147 17 131 0.7 757,636 7,667,066
NVO-16368 Stream Miralga 0.5 0.09 142 11 101 0.4 757,815 7,667,122
NVO-16369 Stream Miralga 1.0 0.16 130 18 116 0.6 757,847 7,667,106
NVO-16371 Stream Miralga 1.0 0.16 123 24 123 0.7 758,263 7,666,822
NVO-16372 Stream Miralga 2.0 0.16 132 19 133 0.6 758,265 7,666,831
NVO-16373 Stream Miralga 0.5 0.13 117 14 138 0.7 758,145 7,666,476
NVO-16374 Stream Miralga 2.0 0.06 102 10 118 0.7 758,142 7,666,465
NVO-16375 Stream Miralga 0.5 0.13 94 13 133 0.6 757,852 7,666,683
NVO-16376 Stream Miralga 0.6 0.15 74 18 118 0.6 757,843 7,666,674
NVO-16377 Stream Miralga 0.7 0.08 100 15 112 0.4 759,292 7,666,945
NVO-16378 Stream Miralga 0.6 0.11 114 18 132 0.5 759,329 7,666,908
NVO-16379 Stream Miralga 0.5 0.07 81 21 95 0.4 759,345 7,666,907
NVO-16380 Stream Miralga 1.0 0.11 81 13 107 0.4 759,106 7,666,677
NVO-16381 Stream Miralga 0.8 0.10 195 20 155 0.7 759,090 7,666,700
NVO-16382 Stream Miralga 0.5 0.03 28 7 38 0.6 761,662 7,655,617
NVO-16383 Stream Miralga 2.0 0.03 56 5 70 0.3 762,188 7,655,318
NVO-16384 Stream Miralga 1.0 0.03 67 7 86 0.3 762,173 7,655,332
NVO-16386 Stream Miralga 0.5 0.03 81 6 77 0.4 762,272 7,654,725
NVO-16387 Stream Miralga 1.0 0.03 64 6 82 0.3 761,875 7,654,682
NVO-16388 Stream Miralga 0.5 0.03 54 6 73 0.5 761,909 7,654,734
NVO-16389 Stream Miralga 0.5 0.03 39 6 57 0.5 761,529 7,655,175
NVO-16390 Stream Miralga 0.5 0.03 66 5 73 0.4 761,509 7,655,178
NVO-16391 Stream Miralga 0.5 0.03 46 6 61 0.5 761,519 7,655,247
NVO-16392 Stream Miralga 0.5 0.03 65 5 104 0.5 759,997 7,656,120
NVO-16393 Stream Miralga 0.5 0.06 92 8 128 0.5 759,955 7,655,795
NVO-16394 Stream Miralga 1.0 0.03 77 4 123 0.4 759,924 7,655,782
NVO-16396 Stream Miralga 0.5 0.08 85 7 107 0.5 760,264 7,655,541
NVO-16397 Stream Miralga 0.5 0.03 83 4 123 0.4 760,613 7,655,338
NVO-16398 Stream Miralga 0.5 0.03 95 9 107 0.7 760,612 7,655,366
NVO-16399 Stream Miralga 0.5 0.06 113 6 114 0.5 760,816 7,655,348
NVO-16400 Stream Miralga 0.5 0.06 86 12 98 0.4 761,162 7,655,284
NVO-16511 Stream Miralga 0.5 0.03 60 6 100 0.4 760,648 7,657,239
NVO-16512 Stream Miralga 2.0 0.08 58 8 110 0.4 760,634 7,657,240
NVO-16513 Stream Miralga 0.8 0.05 61 7 99 0.4 760,488 7,657,194
NVO-16514 Stream Miralga 0.5 0.03 36 10 66 0.5 760,563 7,656,936
NVO-16515 Stream Miralga 2.0 0.03 70 6 111 0.4 760,689 7,656,784
NVO-16516 Stream Miralga 0.5 0.03 41 5 74 0.4 760,696 7,656,803
Sample ID Type Project Au (ppb) As (ppm) Cu (ppm) Pb (ppm) Zn (ppm) Mo (ppm) Easting MGA 2020 Z50 Northing MGA 2020 Z50
H9594 Soil Shady Camp West 1.0 4 60 10 57 0.6 761,199 7,656,279
H9595 Soil Shady Camp West 1.0 3 47 8 52 0.7 761,239 7,656,279
H9596 Soil Shady Camp West 1.0 5 31 10 39 0.5 761,279 7,656,278
H9631 Soil Shady Camp West 0.5 3 164 6 39 0.4 761,479 7,656,279
H9632 Soil Shady Camp West 2.0 3 109 8 52 0.6 761,519 7,656,279
H9633 Soil Shady Camp West 0.5 3 79 8 64 0.5 761,559 7,656,279
H9640 Soil Shady Camp West 5.0 3 32 28 16 0.6 761,799 7,656,278
H9641 Soil Shady Camp West 12.0 100 83 17 36 3.7 761,838 7,656,278
H9642 Soil Shady Camp West 4.0 16 94 21 130 0.9 761,879 7,656,279
H9643 Soil Shady Camp West 1.0 5 39 8 74 0.6 761,920 7,656,279
H9644 Soil Shady Camp West 1.0 4 50 9 50 0.8 761,960 7,656,278
H9597 Soil Shady Camp West 1.0 6 73 17 44 0.9 761,320 7,656,279
H9598 Soil Shady Camp West 2.0 3 52 9 52 0.5 761,359 7,656,278
H9599 Soil Shady Camp West 2.0 3 59 8 49 0.5 761,399 7,656,278
H9630 Soil Shady Camp West 1.0 4 100 9 44 0.7 761,439 7,656,279
H9634 Soil Shady Camp West 0.5 3 54 8 41 0.5 761,599 7,656,279
H9636 Soil Shady Camp West 26.0 4 250 20 32 0.5 761,648 7,656,278
H9637 Soil Shady Camp West 13.0 4 107 22 27 0.4 761,679 7,656,278
H9638 Soil Shady Camp West 7.0 4 71 15 19 1.1 761,720 7,656,279
H9639 Soil Shady Camp West 11.0 5 105 22 26 1.0 761,759 7,656,278
H9646 Soil Shady Camp West 2.0 4 67 9 75 0.7 761,999 7,656,278
H9647 Soil Shady Camp West 0.5 3 40 24 71 0.5 762,040 7,656,279
H9648 Soil Shady Camp West 5.0 5 61 51 112 0.8 762,079 7,656,279

Visual wire gold observations (Bamboo)

(All sample locations are GPS located on MGA_2020 zone 50.)

Sample ID Type Project Mineral observed Visual estimate (%) Description mineral size (mm) Easting Northing
N/A Detected Bamboo Native Gold N/A Wire gold 220,735 7,673,280

Appendix 2 - JORC Code, 2012 Edition – Table 1

Section 1: Sampling Techniques and Data

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

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 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 (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.
  • Rock chips samples were collected by grab sampling 1 – 3 kg of material which were dispatched to Intertek Genalysis, Western Australia for analysis. Sample sites were selected based to be representative on the lithology sampled, and the same sampling technique was employed at each sample site where possible.
  • Stream sediment samples were sieved to < 0.9 mm and submitted to Intertek where they were dried and pulverized to 75 µm or better and analysed using aqua regia and BLEG (Bulk Leach Extractable Gold) 500 g cyanide leach with MS finish for Au, Pt, Pd and Ag.
  • Soil samples of 200g were collected from small pits 2 cm – 20 cm depth and sieved to <80#. Analysis depends on anticipated target mineralisation and includes aqua regia for all soils.
  • pXRF readings of soils were taken using a NITON XLT5 model and were used to aid field interpretation and identification of anomalous target mineralogy and pathfinder elements. The Niton pXRF machine was calibrated daily.
  • Wire gold specimens were detected by hand using a Minelab GPZ 7000 metal detector.
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).
  • No drilling was undertaken.
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.
  • No drilling was undertaken.
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.
  • No drilling was undertaken.
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.
  • Rock chip samples were dried, crushed and pulverised (SP64) by Intertek Genalysis to create a 50 g charge, then assayed for Au (+/- Pt and Pd) by fire assay FA50/OE and for 48 elements using four acid digest – MS finish (4A/MS).
  • Stream sediment samples were dried and pulverized to 75 µm or better (prep code SP02), with a > 85% pass, then analysed for aqua regia for 33 elements. In addition, the samples are analysed via BLEG (Bulk Leach Extractable Gold) 500 g cyanide leach with MS finish for Au, Pt, Pd and Ag.
  • Soil samples required no prep and were analysed for 32 elements by aqua regia digest with MS finish (lab method AR25/MS).
  • pXRF readings of soils were taken using a NITON XLT5 model and were used to aid field interpretation and identification of anomalous target mineralogy and pathfinder elements. The Niton pXRF machine was calibrated daily.
  • The sampling techniques and sample size is considered appropriate for this style of mineralisation.
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 (if lack of bias) and precision have been established.
  • The rock chip sample assay methodology noted above is considered appropriate for the style of mineralisation tested. The method includes inserting 2 CRM standards and 2 blanks per 100 samples or at least one of each per sample submission.
  • The soil and stream sample assay methodology has low level detection for gold and multi-elements and is considered appropriate for soil geochemistry for outcropping or near surface mineralisation. The method includes insertion of at least 2 blanks 2 CRM standards and 4 field duplicates per 100 samples.
  • pXRF readings of soils were taken using a NITON XLT5 model and were used to aid field interpretation and identification of anomalous target mineralogy and pathfinder elements. This is appropriate for first pass reconnaissance and anomaly definition. The machine is calibrated daily and at least four CRMs are inserted per 100 samples and at the start and end of the day.
  • No QAQC issues were detected.
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.
  • Primary data was collected in the field and stored using database compatible excel templates which were then forwarded to the database manager email for upload to the Geobank (v2022.5) database, buffered through a validation portal that ensures code and primary record compliance. Geobank is a front-end UX/UI tender software platform (developed and sold by Micromine) attached to a SQL v15.1 server.
  • Assay data were loaded from lab certificates received from the registered laboratory by an internal database manager or external database consultant, and industry-standard audit trails and chain-of-custody was adhered to.
  • Verification included checking the data against original logs and utilising laboratory certificates.
  • No adjustments of the assay data were made.
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.
  • All surface sample reconnaissance locations were recorded in by hand-held GPS using the GDA 2020 zone 50 co-ordinate system.
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. 
  • Limited rock samples are taken and are indicative of potential grade tenor. These do not indicate any continuity or scale potential.
  • Limited stream samples are taken and provide a vector towards potential mineralisation but are not indicative of grade tenor or scale potential.
  • pXRF soil samples at Gully Washer and Fred’s Well East were taken on a nominal 80 m x 40 m grid and 160 m x 20 m spacing respectively.
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.
  • pXRF sample grids were orientated to best intersect the lithological and structural trends at right angles.
Sample security
  • The measures taken to ensure sample security.
  • All samples are stored and managed on site by internal staff. Samples are then transported by reputable companies to a registered laboratory where they are stored in a locked facility before being tracked and processed through the preparation and analysis system at the laboratory.
Audits or reviews
  • The results of any audits or reviews of sampling techniques and data.
  • No audits have been undertaken.

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.
  • The Gully Washer and Fred’s Well East prospects are part of the Miralga Project and are located on Exploration License E45/4922, approximately 25 km west of Marble Bar. The tenement is 100% held by Nullagine Gold Pty Ltd, a wholly owned subsidiary of Novo.
  • There are no known Registered Heritage Sites within this tenement.
  • A geological heritage site is located within the Dresser Formation and relates to Archean stromatolites. A larger reserve is planned to further expand the protection of these oldest fossils. As the geological heritage site is related to the Dresser Formation where stromatolites occur, it is not expected to impact on the remainder of the tenement prospective for porphyry mineralisation.
  • The prospects fall under the granted Nyamal Native Title determination WC1999/008 and is subject to a land access and mineral exploration agreement with the Native Title Holders.
  • The tenements are currently in good standing and there are no known impediments.
Exploration done by other parties
  • Acknowledgment and appraisal of exploration by other parties.
  • In 1969 – 1970, Anglo American conducted a large stream sampling program comprising 1,345 samples, analysed for Cu, Ni, Pb, and Zn.
  • AMAX conducted surface sampling and costeaning during 1980 and 1981, delineating the Fred’s Well Creek prospect.
  • Haoma Mining explored the district from 1998 to 2018, mostly focussing on the North Pole prospect outside of current Novo tenure, and various small barite deposits.
  • Sipa Resources explored the current Gully Washer prospect and conducted surface rock sampling and drilled six shallow RC drill holes. Results include up to 20.7 g/t Au from rock sampling and a best of 1 m at 6.22 ppm Au from RC chips.
Geology
  • Deposit type, geological setting, and style of mineralisation.
  • The Miralga Project is located on the eastern flank of the North Pole Dome. The North Pole monzogranite has intruded an Archean sequence of mafic to felsic volcanics and volcaniclastics and is prospective for porphyry-style and epithermal vein-style mineralisation within the Panorama Formation. Known porphyry mineralisation is present outside of Novo’s tenure at Miralga Creek B, where Au-Ag-Cu mineralisation is associated with a stock-like Archaean porphyry, high-level dykes and epithermal veins.
  • Wire gold specimens were detected by hand in proximity to one of the Bridget Suite intrusions at Bamboo.
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, including 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 plus 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.
  • No drilling was undertaken.
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.
  • No drilling was undertaken.
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’).
  • No drilling was undertaken.
  • Rock sample results are indicative in nature and, whilst representatively sampling the target lithology, do not contain any width or length information other than a qualitative description of the target.
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.
  • Refer to the body of the release for appropriate maps and diagrams.
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.
  • All rock sample results are reported in Appendix 1. Soil sample analytical and pXRF results are not listed here but summarised in diagrams and in the body of the release.
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.
  • No additional data.
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.
  • Refer to the body of the release.

No Section 3 or 4 report as no Mineral Resources or Ore Reserves are reported in this Appendix

Photos and charts accompanying this announcement are available at

https://www.globenewswire.com/NewsRoom/AttachmentNg/dbf1b3bd-d23b-4ccd-9371-f3501998b247

https://www.globenewswire.com/NewsRoom/AttachmentNg/f5e41ab5-3c97-4968-86fc-93eb00049295

https://www.globenewswire.com/NewsRoom/AttachmentNg/58cc4f17-ca65-41dc-ac96-3a0a5251a446

https://www.globenewswire.com/NewsRoom/AttachmentNg/4af41664-e366-4578-8ad0-e3046cab57cc

https://www.globenewswire.com/NewsRoom/AttachmentNg/7b749f5f-4539-4f30-b3dd-8f1edd89af8c

https://www.globenewswire.com/NewsRoom/AttachmentNg/961c5e62-1ce7-479e-9f7f-acb36055972d

https://www.globenewswire.com/NewsRoom/AttachmentNg/a700a0ec-8e9e-41e2-a34f-be25b4bd3786

https://www.globenewswire.com/NewsRoom/AttachmentNg/dcc3ed88-c7e1-48a4-b3e2-b7319bb9ba88

https://www.globenewswire.com/NewsRoom/AttachmentNg/fc64e1a4-5575-4a39-9b44-f33774aa174d

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