SULTAN RESOURCES LTD

ACN: 623652 522

CORPORATE DETAILS

ASX Code: SLZ

DIRECTORS

STEVEN GROVES MANAGING DIRECTOR

JEREMY KING CHAIRMAN

12[th] April 2021

DAVID LEES NON-EXECUTIVE DIRECTOR

BROAD ZONES OF SILVER MINERALISATION INTERSECTED IN MAIDEN DRILL PROGRAM AT THE TUCKLAN PROJECT, LACHLAN FOLD BELT, NSW

CONTACT

Suite 2, Level 1, 1 Altona Street West Perth WA 6005

www.sultanresources.com.au

[email protected]

Results received from maiden 6 hole, 1,554.3m RC & Diamond drill program.
Broad zones of silver mineralisation intersected:
TRC0001: 88m @ 4.1g/t Ag from 200m, including:
- 8m @ 15.5 g/t Ag from 218m, and
- 2m @ 45.6 g/t Ag from 284m
Mineralisation associated with multi-phase quartz-carbonate-sulphide veining, sericite-chlorite-carbonate alteration and disseminated sulphide mineralisation
Only one hole, TRC0001, pierced the target IP Chargeability bullseye, confirming:
Silver mineralisation is coincident with strong IP chargeability high,
IP is mapping a sliver dominated hydrothermal system which remains open to the east
Results from extension soil sampling reveal a large silver and gold in soil anomaly to the east of the recent drilling, representing a significant target extending from TRC0001
Future work programs including extension IP surveying, and air-core drilling of new Ag-Au targets are being considered.
Surface gold mineralisation from Ordovician volcanics was not adequately tested due to difficult drill conditions - substantial gold potential remains
IP results from Big Hill and Razorback have been received and are being interpreted. Results expected in April.
Significant drilling program to commence in May at Big Hill and Razorback

Sultan Resources Limited (ASX: SLZ) ( Sultan or Company ) is pleased to announce that assay results from the recent Tucklan drilling program have been received. The Company completed drill-testing of Induced Polarisation (IP) anomalies beneath strong gold, silver and copper surface geochemistry at the Tucklan project in February 2021 (see ASX Announcements 07/12/2020, 11/02/2021).

Managing Director, Steve Groves commented: “These results are extremely encouraging. Drill hole TRC0001 pierced the IP bullseye and revealed a significant, silver-rich hydrothermal mineralising vein system. As evidenced by Silver Mines Ltd extensive tenure to the southeast, this part of the Macquarie Arc is highly prospective for silver, and recent surface work at Tucklan has shown that strong silver soil anomalism extends east of TRC0001 and that we are potentially only brushing the edge of a major silver-rich system.

This leaves Sultan with a number of follow up targets at Tucklan, including the original goldbearing altered Ordovician volcanic rocks at surface which remain untested by drilling, the recently discovered silver system to the east, and the potential porphyry system indicated by geophysics at the nearby Glen Athol prospect.”

Drilling Program - Tucklan

During December 2020 and January 2021, the Company completed a maiden drill program at Tucklan with 6 Reverse Circulation holes, including two with diamond tails for a total of 1,544.3m (Figure 1, Appendix 1). Three holes reached their target depth of ~350m and three holes did not reach planned depth due to excessive ground water. The basement geology at Tucklan has been interpretated as Ordovician Tucklan Formation and Silurian Dungeree Volcanics of the Rockley - Gulgong Volcanic Belt, within the Macquarie Arc.

Logging of the drill chips and core revealed broad zones of hydrothermally altered volcaniclastics and coherent volcanic facies that showed multiple generations of veining and sulphide mineralisation in some holes. In particular, hole TRC0001, which targeted a strong IP chargeability ‘bullseye’ anomaly, intersected a 136m down hole zone (172m to 308m) of moderate to intense, multi-generational vein sets and associated disseminated, stringer and vein-hosted sulphide mineralisation within volcaniclastic sediments (Figures 2 and 3). Sulphide mineralisation throughout the interval was dominated by pyrite and pyrrhotite and significant sphalerite (Zn-sulphide), galena (Pb-sulphide) and chalcopyrite (Cu-sulphide) were all noted in some veins.

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TRC0001:
88m @ 4.1g/t Ag from 200m
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Figure 1: Drill collar locations over IP Chargeability pseudo image with Soil Ag >0.21ppm contour (blue outline) and magnetic susceptibility plotted on the right with 5x vertical exaggeration.

Drilling Results

All assay results have been received and have revealed that the vein and sulphide zone in TRC0001 represents a significant intersection of elevated silver mineralisation and confirms that the IP and surface geochemistry are marking the location of a potentially large, and previously undiscovered, hydrothermal, silver-rich mineralising system.

Silver mineralisation is associated with a multiphase quartz-carbonate-sulphide (pyrite – Pyrrhotite – galena – sphalerite – chalcopyrite) vein system with significant disseminated pyrite-pyrrhotite. Veining is hosted in a selectively pervasive, sericite-chlorite-carbonate altered, foliated, biotite-rich volcaniclastic siltstone – sandstone package.

Significant intersections from the drilling include:

Table 1: Significant silver, lead and zinc intersections from TRC0001

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Hole ID From(m) To (m) Interval m) Ag g/t Pb ppm Zn ppm
TRC0001 20 42 22 1.41 50 207
200 288 88 4.14 305.5 229
Incl. 218 226 8 15.5 1119 694.5
Incl. 224 226 2 27.7 1875 1540
and 284 286 2 45.6 3010 1800
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Note: All intervals are down hole widths. Broad significant intersections calculated using >1g/t Ag cut-off and 10m internal dilution. Higher grade zones calculated using >10g/t Ag cut-off with 2m internal dilution. All assay results across relevant elements are included in Appendix 3.

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Figure 2: Section of core from TRC0001 from 284m to 286m showing a zone of carbonate and sulphide veining that returned 2m @ 45.6g/t Ag, 810 ppm Ba, 135 ppm Bi, 170 ppm Cu, 0.3% Pb, 0.18% Zn.

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TRC0001:
88m @ 4.1g/t Ag from 200m
including:
8m @ 15.5 g/t Ag from 218m,
and
2m @ 45.6 g/t Ag from 284m
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Figure 3: Oblique IP Chargeability Section 725350mE with TRC0001 showing the drill hole Ag assays (ppm) histogram plotted on IP Chargeability cross section (60% transparent)

Regional Exploration Potential

The Tucklan silver discovery lies at the north western end of a long zone of crustal extension on the eastern limb of the Macquarie Arc containing a number of silver deposits and exploration prospects (Figure 4). The most significant of these is the Bowden’s Silver deposit, which the owners Silver Mines Ltd report is the largest undeveloped silver deposit in Australia (source: silvermines.com.au/projects/bowdens-silver-project/). Most of the silver-lead-zinc mineralisation at Bowden’s is hosted by the Early Permian silicic and felsic Rylstone Volcanics on the north eastern flank of the exposed Lachlan Fold Belt. These volcanics overlie basement rocks containing Ordovician and Silurian to Devonian shallow marine to subaerial volcanics and sediments (host rocks at Tucklan). The Rylstone Volcanics have not been identified on EL8734.

Silver Mines Ltd report that drilling beneath the Permian-hosted mineralisation has intersected highgrade silver and gold mineralisation in the basement lithology within porphyry intrusives (see ASX:SVL Announcement 19/02/2018) and interpret these results to represent the feeder, or source to the Bowden’s silver deposit. Silver Mines consider there to be great potential for further mineralisation in

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the basement rocks in the form of high-grade vein-hosted zones as well as a potentially mineralised causative intrusion.

Another significant silver prospect in Silver Mines’ portfolio and about 60 km southeast of Tucklan is the Barabolar Prospect where of several intrusive phases including diorite and quartzolite intrude Ordovician stratigraphy consisting of volcanics, shales, and calcareous mudstones (replaced with skarn mineralisation). Mineralisation is observed in volcanics, the skarn replacement and porphyry intrusive rocks (silvermines.com.au/projects/barabolar-project/).

Silver Mines highly prospective portfolio coupled with Sultan’s recent exploration success at Tucklan demonstrate that the eastern limb of the Macquarie Arc is emerging as a region with significant potential for the discovery of deposits ranging across a variety of intrusive-related mineral systems.

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Figure 4: Location of the Tucklan silver discovery in relation to the Bowden’s Silver Deposit and proximity to Silver Mines exploration tenure

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Tucklan Soil Sampling Extension

Sultan has recently completed further soil sampling across a 100m x 100m sample grid to the south east of the previous soil sampling program at Tucklan. This work has increased the size of the NW-SE striking, low level Au (>11.7ppb Au) anomaly and defined a new, large silver anomaly (>0.21ppm Ag) that extends over a 1.5km x 0.5km area immediately to the east of TRC0001 (Figures 5 & 6). Pathfinder elements associated with strong silver anomalism include Au+Ba+Be+Cd+Pb+W+Tl. The strong silver anomalism immediately to the east of TRC0001 indicates that the recent drilling has intersected the edge of a large silver-rich mineralising system and future work should focus on defining the extents and tenor of this system in the area of strongest silver anomalism.

The large gold anomaly at Tucklan is coincident with a number of key pathfinder elements such as HgAg-Te-Se-Bi-W-Pb-As-Sb-Cd and historical gold workings including numerous prospecting pits, alluvial workings, a shallow shaft and adit are also evident across the zone. The recent drilling did not effectively test for the deep source of gold anomalism at Tucklan.

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TRC0001:
88m @ 4.1g/t Ag from 200m
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Figure 5: Gridded image of soil Ag response in relation to the recent drilling at Tucklan. Note the elevated silver anomalism immediately to the east of TRC0001.

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TRC0001:
88m @ 4.1g/t Ag from 200m
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Figure 6: Outline of soil anomalies in Silver (blue, >0.21ppm) and gold (yellow, > 7.2ppb) in relation to the recent drilling.

Future Work Program

Tucklan

A number of target types have been identified across the Tucklan licence, including the recently discovered volcaniclastic-hosted silver mineralisation, the interpreted epithermal gold mineralisation indicated by rock sampling and mapping at surface (see ASX Announcement 02/06/2020) and potential deeper porphyry systems indicated by previous geophysical work at Glen Athol (see ASX Announcement 20/10/2020). Further IP and soil sampling have recently been completed at Glen Athol and results are awaited.

Sultan have demonstrated that high-quality exploration including geological mapping, detailed soil sampling and IP surveying have resulted in the discovery of a significant silver-rich hydrothermal mineralising system in the first drill hole on the prospect. This new discovery represents a very significant target and the Company is assessing future work programs at Tucklan including aircore drilling and further IP to the east of TRC0001, within the large silver anomaly, to increase the understanding and identify further drill targets. Exploration based on the pending IP and soil results will also continue at Glen Athol with the aim of identifying potential porphyry drill targets.

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Big Hill

IP survey results across the Big Hill and Razorback porphyry target have been received and are being interpreted by Sultan and its technical consultants. This work is well advanced and once finalised, the results and follow up work program will be released to the market.

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~70 km
Bowdens
Silver
Deposit
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Figure 7: Location Map – Sultan Tenements over the prospective Macquarie Arc sequence

This announcement is authorised by Steve Groves, Managing Director

For further information contact: Managing Director Steve Groves [email protected]

Investor Relations

Peter Taylor [email protected] 0412 036 231

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Competent Persons Statement

The information in this report that relates to Exploration Targets and Exploration Results is based on historical exploration information compiled by Mr Steven Groves, who is a Competent Person and a Member of the Australian Institute of Geoscientists. Mr Groves is Managing Director and a full-time employee of Sultan Resources Limited. Mr Groves has sufficient experience that is relevant to the style of mineralisation and type of deposit under consideration and to the activity being undertaken to qualify as a Competent Person as defined in the 2012 Edition of the “Australasian Code for the reporting of Exploration Results, Mineral Resources and Ore Reserves”. Mr Groves consents to the inclusion in the report of the matters based on his information in the form and context in which it appears.

Disclaimer

In relying on the above mentioned ASX announcements and pursuant to ASX Listing Rule 5.23.2, the Company confirms that it is not aware of any new information or data that materially affects the information included in the abovementioned announcements.

About Sultan Resources

Sultan Resources is an Australian focused exploration company with a portfolio of quality assets in emerging discovery terranes currently targeted by successful explorers such as Newcrest Mining, Alkane Resources, Gold Road Resources, and Sandfire Resources. Sultan’s tenement portfolio includes prospective targets for porphyry Au-Cu, structurallyhosted gold, Nickel, Cobalt and base metals and include tenements located in the highly prospective Lachlan Fold Belt of Central NSW as well as projects located within the southern terrane region of the Yilgarn Craton in south and south eastern Western Australia. Sultan’s board and management strategy is for a methodical approach to exploration across the prospects in order to discover gold and base metals that may be delineated via modern exploration techniques and exploited for the benefit of the company and its shareholders.

Appendix 1: Collar Details of Drilled Holes

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HoleID EASTING NORTHING RL AZI DIP DEPTH
TRC0001 725403 6442147 470 281 -60 352.1
TRC0002 725546 6442058 463 270 -60 348
TRC0003 724993 6442500 462 215 -60 174
TRC0004 725196 6442751 452 225 -60 180
TRC0005 725046 6442596 452 225 -60 162
TRC0006 724982 6442413 471 233 -60 328.2
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Ed Appendix 2: JORC Code, 2012 Edition Table 1 – Colossus MetalsSection 1 Sampling Techniques and Data

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

Criteria JORC Code explanation Sampling  Nature & quality of sampling (e.g. cut channels, random chips, or specific techniques 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 & 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.

Commentary

Rock sampling program

Rock chip samples were taken in the during field inspection of the Tucklan gold target
Rock samples were collected from surface outcrop and float
Outcrop samples are resistant portions of the local geology and are considered to be in situ. Float samples are interpreted to have been sourced from local area..
Samples weighing up to several kilograms were collected

soil sampling program

All soil sample points were located using a hand-held GPS with +/-5m accuracy utilising MGA zone 55 (GDA94) coordinate system. Surface organic matter was removed from the sample site using a hand pick and shovel and a 25cm x 25cm x 25cm deep hole was dug using a mattock, with a sample of primarily B soil horizon collected. The soil sample was screened using a 3mm mesh aluminium sieve and a 200-250 gram sub sample of -3mm fraction was retained in a labelled soil geochemical bag for analysis. Soil sample IDs and locations are stored digitally in a register which also notes sample content and conditions. External certified reference material / standards, blanks and duplicates are submitted every 50th, 51st and 52nd sample respectively for QAQC purposes.

Drilling	Drill type (eg core, reverse circulation, open-hole hammer, rotary air blast,	 All 6 drill holes commenced with Reverse Circulation drilling using a track
techniques	auger, Bangka, sonic, etc.) & details (e.g. core diameter, triple or standard	mounted drill rig –
	tube, depth of diamond tails, face-sampling bit or other type, whether core is oriented & if so, by what method, etc.).	 RC Hole Depths are as follows:
		HoleID RC - DEPTH
		TRC0001 174

Criteria	JORC Code explanation	Commentary
		TRC0002 348 TRC0003 174 TRC0004 180 TRC0005 162 TRC0006 168  Diamond tails were added to TRC0001 and TRC0006 using truck mounted UDR 1000 drill rig  TRC0006 – Drilled from 168 – 173.4m (5.4m) HQ3 before casing off, reducing to NQ2 and drilling from 173.4 to 328.1m (154.7m) NQ2  TRC0001 – Drilled from 174 – 179.6m (5.6m) HQ3 before casing off, reducing to NQ2 and drilling from 179.6 to 352.10m (172.5m) NQ2  Both single shot and final multishot survey data was completed with a Axis Champgyro  Core orientation was completed using Boart Longyear Truecore orientation system
Drill sample	 Method of recording & assessing core & chip sample recoveries & results	 The RC rig was fitted with a cone splitter with adjustable ports at the bottom
recovery	assessed.	of the cyclone. At the end of each 1m, the sample is dropped into the cone
	 Measures taken to maximise sample recovery & ensure representative nature of the samples.	splitter with the sample bag attached to the right side port. The samples were collected on 2m composites, with the sample bag removed every 2m of drilling. Field duplicates were collected every 50 samples with a second
	 Whether a relationship exists between sample recovery & grade & whether	sample bag attached to the left side port.
	sample bias may have occurred due to preferential loss/gain of fine/coarse material.	 Rock chips were collected on 1m intervals from the excess sample bags, these
		samples were sieved and washed and collected into plastic chip trays.
		 Drill hole data, samples and geology logging is recorded on a purpose
		designed logging excel spreadsheet and stored on the company online storage
		site.
		 Diamond core was extracted from the inner tube and placed into plastic core
		trays at the drill rig. Core was transported to a core facility for processing and
		sampling. Recoverywas assessed between core blocks and visual examination

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Criteria	JORC Code explanation	Commentary
		of the core in the trays. Orientation was completed by reconstructing the core in it’s original position using v rails and the orientation marks placed on the core by the drillers and marking the orientation line up and down the section.  Core was cut using an automatic Almonte core saw.  Sampling was composited on 2m per sample of half core for the NQ2 core and 1m samples of half core for the HQ3 core N/A
Logging	 Whether core & chip samples have been geologically & geotechnically logged to a level of detail to support appropriate Mineral Resource estimation, mining studies & metallurgical studies.  Whether logging is qualitative or quantitative in nature. Core (or costean, channel, etc.) photography.  The total length & percentage of the relevant intersections logged.	Reverse Circulation and Diamond Drilling logging  Geological logging of the diamond core has been completed and recorded on excel spreadsheet logging system, RC geological logging is yet to be recorded on excel spreadsheet logging system, although quick logs have been completed.  All core has been meter marked, Recovery and RQD completed, Orientated, alpha and beta measurements on structures and vein sets, core photography and sampling has been completed and recorded on the company logging and sampling excel spreadsheet  The description is qualitative and includes lithology, alteration and mineralisation
Sub-sampling	 If core, whether cut or sawn & whether quarter, half or all core taken.	Rock and soil sampling program
techniques & sample preparation	 If non-core, whether riffled, tube sampled, rotary split, etc.& whether sampled wet or dry.	 The sample preparation for both rock and soils follows industry best practise involving oven drying, crushing and pulverisation
	 For all sample types, the nature, quality & appropriateness of the sample	Reverse Circulation and Diamond Drilling sampling
	preparation technique.	 The sample preparation for both RC and DD follows industry best practise
	 Quality control procedures adopted for all sub-sampling stages to maximise	involving oven drying, crushing and pulverisation
	representivity of samples.
		 All diamond core is half core, with half being sent for analysis and half being
	 Measures taken to ensure that the sampling is representative of the in situ material collected, including for instance results for field duplicate/second-	kept. Duplicates are collected every 50m and consist of quarter core
	half sampling.	 All Reverse Circulation drilling was sampled using a cone splitter on the
		bottom of the rig cyclone. The right port collects the original sample, with the
		leftport used for duplicates. The level of the splitter is frequentlychecked by

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Criteria	JORC Code explanation	Commentary	Commentary
	 Whether sample sizes are appropriate to the grain size of the material being sampled.	the company representative at the rig and cleaned as required with compressed air, wet samples have been collected, these samples are noted in the company sampling and logging excel spreadsheet.  External certified reference material / standards, blanks submitted every 50th, 51st sample respectively for QAQC purposes for diamond drilling samples.  External certified reference material / standards, blanks and duplicates are submitted every 50th, 51st and 52nd sample respectively for QAQC purposes for reverse circulation samples. Both Reverse Circulation and Diamond drill core sampling are appropriate for the rock types intersected and follows industry best practice
Quality of	 The nature, quality & appropriateness of the assaying & laboratory		Reverse Circulation and Diamond drill samples are analysed for 48 elements
assay data &	procedures used & whether the technique is considered partial or total.		including Ag, Al, As, Ba, Be, Bi, Ca, Cd, Ce, Co, Cr, Cs, Cu, Fe, Ga, Be, Hf, In, K,
laboratory	 For geophysical tools, spectrometers, handheld XRF instruments, etc., the		La, Li, Mg, Mn, Mo, Na, Nb, Ni, P, Pb, Rb, Re, S, Sb, Sc, Se, Sn, Sr, Ta, Te, Th,
tests	parameters used in determining the analysis including instrument make &		Ti, Tl, U, V, W, Y Zn and Zr using method ME-MS61 (four acid ICP-MS). Gold
	model, reading times, calibrations factors applied & their derivation, etc.		will be analysed separately using ALS method Au-AA22, with a lower
	 Nature of quality control procedures adopted (e.g. standards, blanks, duplicates, external laboratory checks) & whether acceptable levels of		detection limit of 0.001 ppm. Soil Samples were analysed for 53 elements including Au, Ag, Al, As, B, Ba,
	accuracy (i.e. lack of bias) & precision have been established.		Be, Bi, Ca, Cd, Ce, Co, Cr, Cs, Cu, Fe, Ga, Ge, Hf, Hg, In, K, La, Li, Mg, Mn, Mo,
			Na, Nb, Ni, P, Pb, Pd, Pt, Rb, Re, S, Sb, Sc, Se, Sn, Sr, Ta, Te, Th, Ti, Tl, U, V, W,
			Y, Zn & Zr using method AuME-ST44.
			External certified reference material / standards, blanks and duplicates are
			submitted every 50th, 51st and 52nd sample respectively for QAQC
			purposes.
			QAQC samples are analysed on return of assay results, CRM are tested
			against certified values and pass is awarded if results fall within 3 standard
			deviations of the mean, a failure of results and/or investigation with the
			laboratory if results fall outside 3 standard deviations of the mean certified
			value. Duplicates are assessed paired against each other and blanks are
			checked for elevated elements of interest.

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Criteria JORC Code explanation Commentary
Verification  The verification of significant intersections by either independent or  All data are verified by at least two experienced geologists.
of sampling alternative company personnel.  Data are stored in a digital database and interrogated using the ioGas [TM]
& assaying  The use of twinned holes. geochemical software suite.
 Documentation of primary data, data entry procedures, data verification,
data storage (physical & electronic) protocols.
 Discuss any adjustment to assay data.
Location of  Accuracy & quality of surveys used to locate drill holes (collar & down-hole  A handheld GPS was used to locate each sample point. Accuracy of +/- 5m is
data points surveys), trenches, mine workings & other locations used in Mineral considered reasonable
Resource estimation.
 MGA94, Zone 55
 Specification of the grid system used.
 Elevation were in AHD (MGA94, Zone 55)
 Quality & adequacy of topographic control.
Data spacing  Data spacing for reporting of Exploration Results.  Soil samples from the are collected across a grid spaced at
& distribution  Whether the data spacing & distribution is sufficient to establish the degree  Tucklan 100m x 100m sample spacing
of geological & grade continuity appropriate for the Mineral Resource &  These spacings are considered reasonable to provide sufficient
Ore Reserve estimation procedure(s)&classifications applied. geochemical coverage over the target types sought.
 Whether sample compositing has been applied.  For Reverse Circulation drill chips, 2m composite samples were collected,
this is considered sufficient for the commodities under exploration
 HQ3 diamond core has been sampled on 1m intervals
 NQ2 diamond core has been samples on 2m composite intervals.
 The sample spacing and compositing is considered reasonable to provide
sufficient geochemical results for the target types sought.
Orientation of  Whether the orientation of sampling achieves unbiased sampling of possible  Drilling was designed to intersect the recorded regional faults at as close as
data in structures & the extent to which this is known, considering the deposit type. reasonable possible to perpendicular
relation to  If the relationship between the drilling orientation & the orientation of key
geological mineralised structures is considered to have introduced a sampling bias, this
structure should be assessed & reported if material.
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Criteria	JORC Code explanation	Commentary
Sample security	 The measures taken to ensure sample security.	All geochemical samples are selected by geologists in the field and delivered to the lab by Sultan Resources contract field staff,
Audits or	 The results of any audits or reviews of sampling techniques & data.	 Not applicable
reviews

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(Criteria listed in the preceding section also apply to this section.)
Criteria JORC Code explanation Commentary
Mineral  Type, reference name/number, location & ownership including agreements  The licences include EL8734, EL8704 and EL8735, which together cover a total area
tenement & or material issues with third parties such as joint ventures, partnerships, of approximately 326 km2 within the Lachlan Fold Belt of central NSW.
land tenure overriding royalties, native title interests, historical sites, wilderness or
All licences are in good standing
status national park & environmental settings.
 The security of the tenure held at the time of reporting along with any known
impediments to obtaining a licence to operate in the area.
Exploration  Acknowledgment & appraisal of exploration by other parties.  Previous exploration over EL8734 has been limited. Work reported was generally
done by other generative in nature and at a reconnaissance level.
parties
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Criteria	JORC Code explanation	Commentary
Mineral tenement & land tenure status	 Type, reference name/number, location & 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 & environmental settings.  The security of the tenure held at the time of reporting along with any known impediments to obtaining a licence to operate in the area.	 The licences include EL8734, EL8704 and EL8735, which together cover a total area of approximately 326 km2 within the Lachlan Fold Belt of central NSW. All licences are in good standing
Exploration done by other parties	 Acknowledgment & appraisal of exploration by other parties.	 Previous exploration over EL8734 has been limited. Work reported was generally generative in nature and at a reconnaissance level.
Geology	 Deposit type, geological setting & style of mineralisation.	The Project lies 45km northeast of the Boda Cu-Au porphyry discovery within the Late
		Ordovician – Early Silurian Tucklan Formation, Rockley - Gulgong Volcanic Belt,
		Macquarie Arc. The Tucklan Formation is considered to be synchronous with Phase 4
		volcanism in the Macquarie Arc which is associated in time and space with the largest
		porphyry Au-Cu deposits. It is associated with historical gold workings that include
		numerous prospecting pits, plus a shallow shaft and adit. These form part of the
		overlooked & extensive Tucklan gold field. Bowdens Silver deposit is located 70km to
		the southeast of the project area.
		The Lachlan Orogen is approximately 700 km wide and 1000 km long and has disputed
		complex evolutionary history. The Macquarie Arc is part of the eastern sub-province of
		the Lachlan Orogen and is the host to numerous porphyry Au–Cu deposits. It consists
		mainlyof subduction-related Ordovician intermediate and mafic volcanic,volcaniclastic

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Criteria JORC Code explanation Commentary
and associated intrusive rocks and was accreted to Gondwana in the Early Silurian, and
underwent rifting and burial in the Middle to Late Silurian.
It consists of four structural belts, namely, the western (Junee-Narromine), the central
(Molong), the eastern (Rockley-Gulgong) Belt, and southern (Kiandra) volcanic belts.
These belts have most likely been formed by rifting and dismemberment of a single arc,
which developed along the boundary between the Australian and proto-Pacific plates
during the Ordovician and was subsequently dismembered during the Silurian.
An entirely intra-oceanic setting is postulated for the Macquarie Arc (Crawford et al.,
2007), with four phases of arc-type magmatism, the earliest in the Early Ordovician,
and culminating in the Late Ordovician to Early Silurian. The four phases of volcanism
in the Macquarie Arc relate to distinct groups of porphyritic intrusions that vary from
monzodiorite-diorite through monzonite-granodiorite compositions and correspond
with porphyry copper-gold and epithermal gold-silver mineralisation
Lithology
Based on the work discussed in this document, the rocks at Tucklan are classified to be
of trachy-andesite to alkali basaltic volcano-sedimentary origin.
Drill hole  A summary of all information material to the understanding of the  Eastings, Northings and RL were collected using a handheld GPS locate each drill collar. Accuracy
Information exploration results including a tabulation of the following information for all of +/- 5m is considered reasonable
Material drill holes:
 MGA94, Zone 55
o Easting & northing of the drill hole collar
Elevation were in AHD (MGA94, Zone 55)
o elevation or RL (Reduced Level – elevation above sea level in metres) of EASTIN
the drill hole collar HoleID G NORTHING RL AZI DIP Total DEPTH
TRC0001 725403 6442147 470 281 -60 352.1
o dip & azimuth of the hole TRC0002 725546 6442058 463 270 -60 348
o down hole length & interception depth TRC0003 724993 6442500 462 215 -60 174
TRC0004 725196 6442751 452 225 -60 180
o hole length. TRC0005 725046 6442596 452 225 -60 162
 If the exclusion of this information is justified on the basis that the TRC0006 724982 6442413 471 233 -60 328.2
information is not Material & this exclusion does not detract from the
understanding of the report, the Competent Person should clearly explain
why this is the case.
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Criteria JORC Code explanation Commentary
Data  In reporting Exploration Results, weighting averaging techniques, maximum  N/A
aggregation and/or minimum grade truncations (e.g. cutting of high grades)&cut-off
methods grades are usually Material & should be stated.
 Where aggregate intercepts incorporate short lengths of high grade results
& longer lengths of low grade results, the procedure used for such
aggregation should be stated & some typical examples of such aggregations
should be shown in detail.
 The assumptions used for any reporting of metal equivalent values should be
clearly stated.
Relationship  These relationships are particularly important in the reporting of  Down hole length only and not true width of mineralisation intervals are reported as
between Exploration Results. true width is unknown.
mineralisatio  If the geometry of the mineralisation with respect to the drill hole angle is
n widths &
known, its nature should be reported.
intercept
 If it is not known & only the down hole lengths are reported, there should be
lengths
a clear statement to this effect (e.g.‘down hole length, true width not
known’).
Diagrams  Appropriate maps & sections (with scales)&tabulations of intercepts should  See maps and figures accompanying this ASX release.
be included for any significant discovery being reported These should
include, but not be limited to a plan view of drill hole collar locations &
appropriate sectional views.
Balanced  Where comprehensive reporting of all Exploration Results is not practicable,  Reference has been made to anomalous levels of geochemical pathfinder elements in
reporting representative reporting of both low & high grades and/or widths should be the document. This interpretation has been determined by experienced Colossus
practiced to avoid misleading reporting of Exploration Results. Metals’ geologists using the ioGas [TM] geochemical software. It is impractical to present
every result for all 53 elements across the sample population in this document. A map
showing the distribution of anomalous Au has been included for reference.
Other  Other exploration data, if meaningful & material, should be reported  The Induced Polarisation (IP) survey method is often used to determine the location
substantive including (but not limited to): geological observations; geophysical survey of disseminated sulphides. Rocks containing sulphide minerals can be more readily
exploration results; geochemical survey results; bulk samples – size&method of charged than barren ground. An external current is applied, and charge separation can
data treatment; metallurgical test results; bulk density, groundwater, occur on sulphide grain boundaries. When the transmitted current is switched off the
geotechnical & rock characteristics; potential deleterious or contaminating decay of the current can be measured.
substances.
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Criteria	JORC Code explanation	Commentary	Commentary
		   	The IP survey was completed by Fender Geophysics. The oversight of the survey and auditing (QAQC) and processing of data acquired was conducted by Alan Ortel, an experienced geophysict. The IP survey array used was Dipole-Dipole with a 100m receiver dipole size and a 100m transmitter dipole size. The transmitter dipole was moved at 100m intervals, achieving a 100m station spacing. All seven (7) lines are orientated North-South and spaced at 200m intervals. The transmitter used is a GDD-Tx4, 5kVA transmitter system and the receiver used in a GDD-Rx32. The survey was collected with a frequency of 0.25Hz. The transmitter and receiver electrode positions are located to hand-held GPS accuracy, generally +-3m (UTM projection GDA94 Zone 55). Other Geophysical data including publicly available magnetic and radiometric surveys have been referred to in interpreting the Tucklan Gold Target. All data are available from the NSW Department of Planning, Industry and Environment MinView website: https://minview.geoscience.nsw.gov.au
Further work	 The nature & scale of planned further work (e.g. tests for lateral extensions		The focus on future work will be to ultimately generate additional targets for deep
	or depth extensions or large-scale step-out drilling).		drilling. Work to enable this will include shallow Aircore drilling, further soil sampling
	 Diagrams clearly highlighting the areas of possible extensions, including the		programs coupled with extension IP geophysics to locate bodies of disseminated
	main geological interpretations & future drilling areas, provided this		sulphides beneath the surface. If sufficient encouragement is gained from this work,
	information is not commercially sensitive.		then further deeper RC or diamond drilling is anticipated.

Appendix 3: Assay Results

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Depth
Depth Au Ag As Ba Bi Cu Mo Pb Zn
Sample_ Hole_ID From S_%
To (m) ppm ppm ppm ppm ppm ppm ppm ppm ppm
Type (m)
RC TRC0001 0 2 0.299 1.85 22.3 740 0.3 156 0.81 151 0.01 288
RC TRC0001 2 4 0.226 1.98 17.2 560 0.27 173 0.24 81 0.005 168
RC TRC0001 4 6 0.068 0.6 8 420 0.25 146.5 0.2 42.1 0.01 167
RC TRC0001 6 8 0.031 0.39 11.2 340 0.24 147 0.17 79.2 0.005 285
RC TRC0001 8 10 0.022 0.32 16.4 290 0.16 116 0.18 87.2 0.005 260
RC TRC0001 10 12 0.026 0.36 59.7 380 0.18 145 0.24 49.2 0.005 214
RC TRC0001 12 14 0.031 0.4 53.7 430 0.24 106.5 0.96 64.2 0.005 123
RC TRC0001 14 16 0.025 0.69 440 750 0.21 148 3.29 87.1 0.005 239
RC TRC0001 16 18 0.053 0.86 762 700 0.38 127.5 1.96 81.3 0.005 211
RC TRC0001 18 20 0.03 0.89 592 760 0.29 126.5 1.18 36.1 0.005 140
RC TRC0001 20 22 0.154 1.13 2240 650 0.23 141.5 1.72 67 0.01 344
RC TRC0001 22 24 0.041 2.52 895 550 0.13 122.5 0.68 42.6 0.01 356
RC TRC0001 24 26 0.044 2.68 309 520 0.13 120.5 1.01 26 0.01 181
RC TRC0001 26 28 0.022 1.3 211 650 0.23 114 1.77 28.2 0.8 130
RC TRC0001 28 30 0.016 1 130 690 0.27 111.5 1.45 25.5 1.17 109
RC TRC0001 30 32 0.007 1.05 340 440 0.23 97.3 2.14 22.3 0.8 161
RC TRC0001 32 34 0.003 1.12 252 350 0.24 112 2.24 41.1 1.1 189
RC TRC0001 34 36 0.003 1 126.5 760 0.16 117 1.75 26.5 1.46 128
RC TRC0001 36 38 0.004 0.98 133.5 850 0.2 121.5 1.83 15.8 1.43 174
RC TRC0001 38 40 0.009 1.1 54.3 860 0.26 111.5 2.44 25.7 1.56 132
RC TRC0001 40 42 0.01 1.63 533 800 0.25 116 2 230 1.59 369
RC TRC0001 42 44 0.002 0.99 84.7 740 0.24 107 1.62 38 1.42 107
RC TRC0001 44 46 0.003 0.78 42.3 670 0.22 105 1.37 17.2 1.15 89
RC TRC0001 46 48 0.001 0.71 27.1 670 0.2 105 1.1 20.5 1.08 88
RC TRC0001 48 50 0.003 0.72 31.6 680 0.23 109 1.35 23.5 1.03 94
RC TRC0001 50 52 0.016 0.9 27.7 730 0.26 138 1.15 21.9 1.45 104
RC TRC0001 52 54 0.005 0.76 24.2 720 0.27 121.5 1.14 21.4 1.24 105
RC TRC0001 54 56 0.001 0.47 32.2 720 0.23 107.5 1.01 19.3 0.99 103
RC TRC0001 56 58 0.002 0.38 17.6 650 0.25 107.5 0.91 24.1 1.14 93
RC TRC0001 58 60 0.001 0.32 27.1 710 0.29 109 1.08 23.5 1.46 90
RC TRC0001 60 62 0.001 0.33 16.7 680 0.28 112 1.09 27.6 1.37 298
RC TRC0001 62 64 0.001 0.28 20 710 0.25 114 1.08 17.6 1.31 116
RC TRC0001 64 66 0.001 0.27 42.9 610 0.23 102 1.16 19.2 1.1 98
RC TRC0001 66 68 0.003 0.25 29.6 670 0.26 110.5 1.08 25.3 1.05 114
RC TRC0001 68 70 0.002 0.22 23.6 650 0.32 115.5 1.17 19.8 1.03 113
RC TRC0001 70 72 0.001 0.17 16.9 670 0.25 105.5 0.97 14 0.93 98
RC TRC0001 72 74 0.001 0.19 15 620 0.34 110.5 1.04 14.1 1.34 109
RC TRC0001 74 76 0.001 0.17 9.2 620 0.27 93.7 0.93 13.7 1.16 86
RC TRC0001 76 78 0.001 0.16 14.5 590 0.29 101.5 1.05 11.2 1.36 85
RC TRC0001 78 80 0.001 0.17 21.1 620 0.28 97.2 1.12 11.7 1.28 85
RC TRC0001 80 82 0.001 0.18 12.6 630 0.34 117.5 1.1 11.3 1.66 81
RC TRC0001 82 84 0.001 0.19 6.2 720 0.37 106.5 1.39 15 2.17 62
RC TRC0001 84 86 0.001 0.2 10.3 700 0.35 100 1.1 15.3 1.85 85
RC TRC0001 86 88 0.001 0.2 11 690 0.38 111.5 1.3 15.6 2.19 125
RC TRC0001 88 90 0.001 0.22 9.3 670 0.38 109.5 1.14 15.5 2.24 72
RC TRC0001 90 92 0.001 0.26 4.4 690 0.46 114.5 1.19 21.2 1.97 93
RC TRC0001 92 94 0.001 0.21 8.2 690 0.39 107.5 1.26 18.1 1.85 69
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