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#SVML Sovereign Metals LTD – Kasiya’s Graphite Suitable for Refractory Use
KASIYA’S GRAPHITE SUITABLE FOR REFRACTORY USE
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Kasiya graphite concentrate confirmed to meet or exceed all critical characteristics required for refractory applications |
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Refractories market is the second largest end-user of natural graphite (24%) after batteries sector (52%) |
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Refractories use coarser (larger) flake graphite products, which typically attract a premium over smaller flake-size products used in the batteries sector |
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In Q4 2024, graphite usable in refractories achieved prices up to US$1,193/t versus smaller flake graphite used in the batteries sector, which sold for US$564/t |
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Kasiya’s incremental cost of graphite production per the recently announced Optimised Prefeasibility results is US$241/t (FOB) |
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Leading German laboratories ProGraphite and Dorfner Anzaplan completed a comprehensive testwork program of Kasiya’s graphite concentrate |
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Results will be used for customer engagement and potential offtake discussions |
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Previous testwork has already confirmed that Kasiya’s graphite can produce outstanding battery anode material |
Sovereign Metals Limited (ASX:SVM; AIM:SVML; OTCQX: SVMLF) (Sovereign or the Company) is pleased to announce that testwork completed on graphite from the Company’s Kasiya Rutile-Graphite Project (Kasiya or the Project) has confirmed Kasiya’s graphite has the key characteristics required for use in refractory applications. The comprehensive testwork programs were completed by ProGraphite GmbH (ProGraphite) and Dorfner Anzaplan (DA) in Germany and demonstrated that Kasiya graphite concentrate contains very low sulphur levels and the absence of other impurities of concern, providing a competitive advantage over other current and potential sources of graphite supply.
Managing Director and CEO Frank Eagar commented: “The refractories market is the second largest end-user of natural graphite and requires larger, coarser graphite flakes with specific chemical and physical properties. We know that almost 70% of Kasiya’s graphite meets the size requirements for refractory applications. Today’s results confirm that our graphite product also meets or exceeds the key chemical and physical properties required to sell into the refractory market.
Combining these results with the excellent results for anode materials testing highlights the premium quality of Kasiya graphite concentrate and provides a very strong foundation for sales and marketing discussions.”
Kasiya Graphite Testwork Update
Sovereign has now completed testwork programs to confirm the suitability of graphite from Kasiya as a product for the two largest end-use markets for natural flake graphite i.e. refractory applications and anode material for use in lithium-ion batteries. Together, these two sectors account for over three-quarters of global natural graphite demand (see Figure 1).
Graphite products for refractory applications typically require larger flake sizes than the smaller graphite flake products used to produce battery anode materials. Larger flake size graphite products tend to attract significantly higher prices than smaller flake products.
In Q4 2024, Syrah Resources Limited (the world’s largest, publicly listed natural graphite producer outside of China) reported a price for smaller flake graphite concentrate to be used for battery anode production of US$564 per tonne (CIF) based on third-party sales. In December 2024, large flake graphite used in the refractory sector achieved prices of up to US$1,193/t (based on data from Benchmark Mineral Intelligence).
The incremental cost of producing a tonne of graphite from Kasiya under Sovereign’s recently announced Optimised Prefeasibility Study is US$241/t (see ASX announcement “Kasiya – Optimised PFS Results” dated 22 January 2025).
Figure 1: Uses of Graphite (Source: European Advanced Carbon and Graphite Association)
Refractory Application Testwork Results Summary
Flake graphite concentrate generated from Kasiya samples were tested for traditional, refractory applications at two leading European laboratories ProGraphite and DA, with the following findings:
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Table 1: Graphite Requirements for Refractory Applications |
Kasiya Graphite |
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High purity graphite concentrate with little impurities |
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High grade, large flakes within graphite concentrate |
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High melting temperature for flake ash residue after combusting graphite |
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High oxidation resistance of graphite concentrate |
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Low levels of volatiles in concentrate |
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Low levels of problematic mineral impurities, including sulphur |
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Low levels of “springback” from compression |
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Customer Engagement and Offtakes
The global refractory market is an estimated €20 Billion worldwide industry and is the largest traditional market for natural flake graphite. Natural flake graphite is added to refractories to improve performance.
Refractories are used to line furnaces and vessels to support high-temperature processing across a wide range of industries, including iron and steel production, non-ferrous metals, cement and lime, glass, and chemicals.
According to the global leader in refractories, RHI Magnesita NV, steel production is the major consumer of refractories, accounting for 60% of global demand. Each tonne of steel requires approximately 10-15kg of refractories.
Other key companies in the refractories market include Vesuvius plc, Krosakai Harima Corporation, Puyang Refractories Group, Chosun Refractories Co, Imerys SA, Shinagwa Refractories, Saint-Gobain, Morgans Advanced Materials and Calderys.
The successful assessment of Kasiya coarse flake for refractory applications will be used for customer engagement and offtake discussions.
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Enquires |
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Frank Eagar, Managing Director & CEO South Africa / Malawi + 27 21 140 3190
Sapan Ghai, CCO London +44 207 478 3900 |
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Nominated Adviser on AIM and Joint Broker |
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SP Angel Corporate Finance LLP |
+44 20 3470 0470 |
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Ewan Leggat Charlie Bouverat |
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Joint Brokers |
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Stifel |
+44 20 7710 7600 |
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Varun Talwar |
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Ashton Clanfield |
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Berenberg |
+44 20 3207 7800 |
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Matthew Armitt |
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Jennifer Lee |
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Buchanan |
+ 44 20 7466 5000 |
Competent Person Statement
The information in this report that relates to Metallurgical Testwork is based on information compiled by Dr Surinder Ghag, PhD., B. Eng, MBA, M.Sc., who is a Member of the Australasian Institute of Mining and Metallurgy (MAusIMM). Dr Ghag is engaged as a consultant by Sovereign Metals Limited. Dr Ghag has sufficient experience, which is relevant to the style of mineralisation and type of deposit under consideration and to the activity which he is undertaking, 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 Ghag consents to the inclusion in the report of the matters based on his information in the form and context in which it appears.
The information in this report that relates to Exploration Results is based on information compiled by Mr Malcolm Titley, a Competent Person who is a member of The Australasian Institute of Mining and Metallurgy (AusIMM). Mr Titley consults to Sovereign Metals Limited and is a holder of ordinary shares and unlisted performance rights in Sovereign Metals Limited. Mr Titley 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 Reporting of Exploration Results, Mineral Resources and Ore Reserves’. Mr Titley consents to the inclusion in the report of the matters based on his information in the form and context in which it appears.
The information in this announcement that relates to operating costs is extracted from an announcement dated 22 January 2025, which is available to view at www.sovereignmetals.com.au. Sovereign confirms that: a) it is not aware of any new information or data that materially affects the information included in the original announcement; b) all material assumptions and technical parameters underpinning the Production Target, and related forecast financial information derived from the Production Target included in the original announcement continue to apply and have not materially changed; and c) the form and context in which the relevant Competent Persons’ findings are presented in this presentation have not been materially modified from the original announcement.
Forward Looking Statement
This release may include forward-looking statements, which may be identified by words such as “expects”, “anticipates”, “believes”, “projects”, “plans”, and similar expressions. These forward-looking statements are based on Sovereign’s expectations and beliefs concerning future events. Forward looking statements are necessarily subject to risks, uncertainties and other factors, many of which are outside the control of Sovereign, which could cause actual results to differ materially from such statements. There can be no assurance that forward-looking statements will prove to be correct. Sovereign makes no undertaking to subsequently update or revise the forward-looking statements made in this release, to reflect the circumstances or events after the date of that release.
The information contained within this announcement is deemed by the Company to constitute inside information as stipulated under the Market Abuse Regulations (EU) No. 596/2014 as it forms part of UK domestic law by virtue of the European Union (Withdrawal) Act 2018 (‘MAR’). Upon the publication of this announcement via Regulatory Information Service (‘RIS’), this inside information is now considered to be in the public domain.
Appendix 1: Detailed Refractory Application Testwork Results
High purity graphite concentrate with little impurities
Kasiya concentrate was determined to have high purity (98%) with no observable natural mineral impurities observed (see Figure 2). Talc, which is not an impurity of concern for refractory applications, was determined to be the minor impurity on analysis of the ash remaining from combusting the graphite.
Figure 2: Kasiya Flake Graphite SEM highlighting clean flakes
High grade, large flakes within graphite concentrate
Natural flake graphite for refractory applications requires high oxidation resistance. Particle size and grade are the two key determinants of oxidation resistance.
There are three different size fractions applicable to refractory graphite products: +300 microns, +180 microns and +150 microns. All three size fractions for Kasiya graphite concentrate demonstrate very high grade, highlighting coarse Kasiya flakes suitability for refractory applications.
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Table 2: Size fraction analysis for Loss-on-Ignition (LOI) and Fixed Carbon Grade |
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Sample |
LOI (%) |
Fixed Carbon (%) |
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+300 microns |
98.69 |
98.50 |
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+180 microns |
98.83 |
98.57 |
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+150 microns |
98.75 |
98.49 |
High melting temperature for flake ash residue
Flake ash is the residue from combusting (burning) graphite. A high flake ash melting temperature is required for refractory applications.
Flake ash from coarse Kasiya flake (>180 microns) has a melting temperature of 1,373°C, above that for flake ash of commercial reference material (>1250°C), and hemisphere temperature of 1,393°C and flow temperature of 1,429°C (Figure 3) i.e. flake ash from coarse Kasiya concentrate exceeds the melting characteristics specification.
Figure 3: Flake ash from Kasiya coarse flake melting testing
High oxidation resistance of graphite concentrate
As reported in the Company’s ASX Announcement dated 21 November 2024, entitled “Positive Initial Test Results For Use Of Kasiya Graphite In Refractories”, and as expected from the high purity of Kasiya coarse fractions (Table 2), Kasiya’s coarse flake has excellent resistance to oxidation. ProGraphite had confirmed Kasiya coarse flake exhibits:
No oxidation below 400°C, only a 6.4% mass loss after four hours at 650°C, and a very low oxidation rate of 1.6% per hour at 650°C.
Comparative testing at DA showed that only a coarse commercial reference material (>300 microns) had a greater resistance than Kasiya coarse flake (>180 microns).
Low levels of volatiles in concentrate
DA measured volatiles content at 0.2%, which is comparable or better than commercial reference materials; ProGraphite measured volatile content at 0.19%-0.26% for various size fractions, significantly lower than what is considered “high volatiles content” at ~0.5% or higher.
High volatiles content can damage the refractory, indicating that Kasiya coarse flake meets this specification.
Low levels of problematic mineral impurities
Sulphur content was measured at 0.03% at DA, noting that Kasiya graphite sulphur levels are low compared to commercial reference material from other sources.
Calcium carbonates (calcite, dolomite) act as a flux, lowering the melting point of other minerals and releasing CO2 when exposed to high temperatures. Consequently, low levels are required in graphite used for refractory applications. Calcium carbonates were not detected in testing of Kasiya concentrate via a range of methods. Other alkalis (sodium, potassium) which can also be reactive in refractory applications were also at low levels.
Low levels of “springback” from compression
Springback is an assessment of the extent of graphite to increase its volume after compression. A low springback is preferred for shape retention e.g. in producing refractory bricks.
Springback of Kasiya graphite was observed to be low and in line with results from Chinese graphite’s, decreasing with particle size (see Table 3).
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Table 3: Springback Analysis of Kasiya Coarse Fractions |
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Sample |
Springback (%) |
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+300 microns |
8.1% |
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+180 microns |
9.2% |
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+150 microns |
11.5% |
Conclusion
Testing of the broad range of criteria on the suitability of natural graphite concentrates for refractory applications confirmed that coarse Kasiya concentrate has the characteristics required for refractory applications – it has high purity, high oxidation resistance, high ash melting temperatures, low levels of volatiles, sulphur and calcium carbonates, and low springback.
Appendix 2: JORC CODE, 2012 EDITION – TABLE 1
SECTION 1 – SAMPLING TECHNIQUES AND DATA
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Criteria |
JORC Code explanation |
Commentary |
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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.
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Metallurgical Composite Sample: The sample was a composite of 24 Hand Auger (HA) and Push Tube (PT) holes drilled in 2021 and 2022 in the Kingfisher pit. All drilling samples within the pit shell were added to the composite resulting in a sample of 2,498kg. Specifically, the composite sample consisted of selected rutile mineralised zones from holes, NSHA0009, 0010, 0056, 0060, 0061, 0074, 0119, 0311, 0343, 0344, 0345, 0350 and NSPT 0011, 0013, 0014, 0015, 0017, 0020, 0021, 0023, 0024, 0025, 0026, 0027. The following workflow was used to generate a pre-concentrate graphite feed at AML: · Wet screen at 2mm to remove oversize · Two stage cyclone separation at a cut size of 45µm to remove -45µm material · Pass +45µm -2mm (sand) fraction through Up Current Classifier (UCC) · Pass UCC O/F through cyclone at cut point of 45µm · Pass UCC O/F cyclone U/F (fine) over MG12 Mineral Technologies Spiral · Pass UCC U/F (coarse) over MG12 Mineral Technologies Spiral · Spiral cons are combined for further processing. Fine and coarse gravity tailing samples contain approximately 75%-80% of the graphite present in the feed sample. The majority of the graphite lost is contained in the -45µm fines. |
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Include reference to measures taken to ensure sample representivity and the appropriate calibration of any measurement tools or systems used.
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Placer Consulting (Placer) Resource Geologists have reviewed Standard Operating Procedures (SOPs) for the collection of HA and PT drill samples and found them to be fit for purpose. Drilling and sampling activities are supervised by a suitably qualified Company geologist who is present at all times. All bulk 1-metre drill samples are geologically logged by the geologist at the drill site. The primary metallurgical composite sample is considered representative for this style of mineralisation. |
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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.
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HA drilling was used to obtain 1-metre samples. The bulk metallurgical sample was a composite of selected samples from routine resource drilling. Existing rutile and graphite exploration results were used to determine the 1-metre intervals suitable to contribute to the two bulk sample composites. |
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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).
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Hand-auger drilling is completed with 75mm diameter enclosed spiral bits with 1-metrelong steel rods. Each 1m of drill sample is collected into separate sample bags and set aside. The auger bits and flights are cleaned between each metre of sampling to avoid contamination. Placer has reviewed SOPs for hand-auger drilling and found them to be fit for purpose and support the resource classifications as applied to the MRE. |
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Drill Sample Recovery |
Method of recording and assessing core and chip sample recoveries and results assessed.
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The configuration of drilling and nature of materials encountered results in negligible sample loss or contamination. Samples are assessed visually for recoveries. Overall, recovery is good. Drilling is ceased when recoveries become poor generally once the water table has been encountered. Auger drilling samples are actively assessed by the geologist onsite for recoveries and contamination. |
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Measures taken to maximise sample recovery and ensure representative nature of the samples.
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The Company’s trained geologists supervise auger drilling on a 1 team 1 geologist basis and are responsible for monitoring all aspects of the drilling and sampling process.
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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.
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No bias related to preferential loss or gain of different materials has occurred. |
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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.
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All individual 1-metre auger intervals are geologically logged, recording relevant data to a set template using company codes.
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Whether logging is qualitative or quantitative in nature. Core (or costean, channel, etc.) photography.
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All logging includes lithological features and estimates of basic mineralogy. Logging is generally qualitative. |
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The total length and percentage of the relevant intersection logged
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100% of samples are geologically logged. |
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Sub-sampling techniques and sample preparation |
If core, whether cut or sawn and whether quarter, half or all core taken.
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Not applicable – no core drilling conducted.
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If non-core, whether riffled, tube sampled, rotary split, etc. and whether sampled wet or dry. |
Primary individual 1-metre samples from all HA and PT holes drilled are sun dried, homogenised and riffle split.
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For all sample types, the nature, quality and appropriateness of the sample preparation technique.
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Metallurgical Composite Sample: 1-metre intervals selected for the 2,498kg metallurgical sample were divided into weathering units. MOTT and PSAP material were combined and homogenised in preparation for dispatch to Australian laboratory Intertek for TGC assay. Per Australian import quarantine requirements the contributing SOIL/FERP material from within 2m of surface was kept separate to undergo quarantine heat treatment at Intertek Laboratory on arrival into Australia. The two sub samples (SOIL/FERP and MOTT/PSAP) were then dispatched from Intertek to AML Laboratory (AML). AML sub-sampled and assayed the individual lithologies prior to combining and homogenising the sample in preparation for test-work. |
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Quality control procedures adopted for all sub-sampling stages to maximise representivity of samples.
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The sample preparation techniques and QA/QC protocols are considered appropriate for the nature of this test-work.
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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.
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The sampling best represents the material in situ. |
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Whether sample sizes are appropriate to the grain size of the material being sampled.
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The sample size is considered appropriate for the nature of the test-work. |
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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. |
Metallurgical Composite Sample: The following workflow was used to generate a graphite product; o Coarse and fine rougher graphite flotation o Polishing grind of coarse and fine rougher graphite concentrate o Cleaner flotation of coarse and fine graphite o Cleaner concentrate sizing at 180µm o Regrind of separate +180µm/-180µm fractions o Three stage recleaner flotation of +180µm/-180µm fractions
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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.
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Acceptable levels of accuracy and precision have been established. No handheld methods are used for quantitative determination.
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Nature of quality control procedures adopted (e.g. standards, blanks, duplicate, external laboratory checks) and whether acceptable levels of accuracy (i.e. lack of bias) and precision have been established.
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Acceptable levels of accuracy and precision have been established in the preparation of the bulk sample composites. |
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Verification of sampling & assaying |
The verification of significant intersections by either independent or alternative company personnel.
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No drilling intersections are being reported. |
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The use of twinned holes.
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No twin holes completed in this program.
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Documentation of primary data, data entry procedures, data verification, data storage (physical and electronic) protocols. |
All data was collected initially on paper logging sheets and codified to the Company’s templates. This data was hand entered to spreadsheets and validated by Company geologists.
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Discuss any adjustment to assay data.
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No adjustment to assay data has been made.
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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.
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A Trimble R2 Differential GPS is used to pick up the collars. Daily capture at a registered reference marker ensures equipment remains in calibration. No downhole surveying is completed. Given the vertical nature and shallow depths of the holes, drill hole deviation is not considered to significantly affect the downhole location of samples. |
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Specification of the grid system used. |
WGS84 UTM Zone 36 South. |
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Quality and adequacy of topographic control. |
DGPS pickups are considered to be high quality topographic control measures. |
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Data spacing & distribution |
Data spacing for reporting of Exploration Results. |
Metallurgical Composite Sample: The hand-auger holes contributing to this metallurgical were selected from pit area Kingfisher and broadly represent early years of mining as contemplated in the OPFS (Approximately the first three years).
It is deemed that these holes should be broadly representative of the mineralisation style in the general area.
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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. |
Not applicable, no Mineral Resource or Ore Reserve estimations are covered by new data in this report. |
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Whether sample compositing has been applied. |
Metallurgical Composite Sample: The sample was composited as described under Sampling Techniques in this Table.
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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
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No bias attributable to orientation of sampling has been identified. |
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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.
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All holes were drilled vertically as the nature of the mineralisation is horizontal. No bias attributable to orientation of drilling has been identified. |
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Sample security |
The measures taken to ensure sample security |
Samples are stored in secure storage from the time of drilling, through gathering, compositing and analysis. The samples are sealed as soon as site preparation is complete.
A reputable international transport company with shipment tracking enables a chain of custody to be maintained while the samples move from Malawi to Australia or Malawi to Johannesburg. Samples are again securely stored once they arrive and are processed at Australian laboratories. A reputable domestic courier company manages the movement of samples within Perth, Australia.
At each point of the sample workflow the samples are inspected by a company representative to monitor sample condition. Each laboratory confirms the integrity of the samples upon receipt. |
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Audits or reviews |
The results of any audits or reviews of sampling techniques and data
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It is considered by the Company that industry best practice methods have been employed at all stages of the exploration.
Malawi Field and Laboratory visits have been completed by Richard Stockwell in May 2022. A high standard of operation, procedure and personnel was observed and reported.
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SECTION 2 – REPORTING OF EXPLORATION RESULTS
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Criteria |
Explanation |
Commentary |
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Mineral tenement & 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 environment settings. |
The Company owns 100% of the following Exploration Licences (ELs) under the Mines and Minerals Act 2019 (Malawi), held in the Company’s wholly-owned, Malawi-registered subsidiaries: EL0609, EL0582, EL0492, EL0528, EL0545, EL0561, EL0657 and EL0710.
A 5% royalty is payable to the government upon mining and a 2% of net profit royalty is payable to the original project vendor.
No significant native vegetation or reserves exist in the area. The region is intensively cultivated for agricultural crops. |
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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 tenements are in good standing and no known impediments to exploration or mining exist. |
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Exploration done by other parties
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Acknowledgement and appraisal of exploration by other parties. |
Sovereign Metals Ltd is a first-mover in the discovery and definition of residual rutile and graphite deposits in Malawi. |
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Geology |
Deposit type, geological setting and style of mineralisation |
The rutile deposit type is considered a residual placer formed by the intense weathering of rutile-rich basement paragneisses and variable enrichment by eluvial processes.
Rutile occurs in a mostly topographically flat area west of Malawi’s capital, known as the Lilongwe Plain, where a deep tropical weathering profile is preserved. A typical profile from top to base is generally soil (“SOIL” 0-1m) ferruginous pedolith (“FERP”, 1-4m), mottled zone (“MOTT”, 4-7m), pallid saprolite (“PSAP”, 7-9m), saprolite (“SAPL”, 9-25m), saprock (“SAPR”, 25-35m) and fresh rock (“FRESH” >35m).
The low-grade graphite mineralisation occurs as multiple bands of graphite gneisses, hosted within a broader Proterozoic paragneiss package. In the Kasiya areas specifically, the preserved weathering profile hosts significant vertical thicknesses from near surface of graphite mineralisation. |
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Drill hole information |
A summary of all information material to the understanding of the exploration results including a tabulation of the following information for all Material drill holes: easting and northings 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; and hole length |
All intercepts relating to the Kasiya Deposit have been included in public releases during each phase of exploration and in this report. Releases included all collar and composite data and these can be viewed on the Company website. There are no further drill hole results that are considered material to the understanding of the exploration results. Identification of the broad zone of mineralisation is made via multiple intersections of drill holes and to list them all would not give the reader any further clarification of the distribution of mineralisation throughout the deposit.
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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 information has been excluded. |
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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. |
No data aggregation was required. |
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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. |
No data aggregation was required. |
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The assumptions used for any reporting of metal equivalent values should be clearly stated. |
Not applicable |
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Relationship between mineralisation widths & intercept lengths |
These relationships are particularly important in the reporting of Exploration Results. |
The mineralisation has been released by weathering of the underlying, layered gneissic bedrock that broadly trends NE-SW at Kasiya North and N-S at Kasiya South. It lies in a laterally extensive superficial blanket with high-grade zones reflecting the broad bedrock strike orientation of ~045° in the North of Kasiya and 360° in the South of Kasiya. No drilling intercepts are being reported. |
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If the geometry of the mineralisation with respect to the drill hole angle is known, its nature should be reported. |
The mineralisation is laterally extensive where the entire weathering profile is preserved and not significantly eroded. Minor removal of the mineralised profile has occurred where alluvial channels cut the surface of the deposit. These areas are adequately defined by the drilling pattern and topographical control for the resource estimate. |
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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 intercepts are being reported. |
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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 the drill collar locations and appropriate sectional views. |
In exploration results and plan view for the samples used in relation to the metallurgical composite test work conducted in this announcement, are included in Sovereign’s announcements dated 30 March 2021, 18 August 2021 and 15 March 2022.
These are accessible on the Company’s and on the ASX websites. |
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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 results are included in this report and in previous releases. These are accessible on the Company’s webpage. |
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Other substantive exploration data |
Other exploration data, if meaningful and material, should be reported including (but not limited to: geological observations; geophysical survey results; geochemical survey results; bulk samples – size and method of treatment; metallurgical test results; bulk density, groundwater, geotechnical and rock characteristics; potential deleterious or contaminating substances. |
Limited lateritic duricrust has been variably developed at Kasiya, as is customary in tropical highland areas subjected to seasonal wet/dry cycles. Lithological logs record drilling refusal in just under 2% of the HA/PT drill database. No drilling refusal was recorded above the saprock interface by AC drilling. Sample quality (representivity) is established by geostatistical analysis of comparable sample intervals.
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Further work |
The nature and scale of planned further work (e.g. test for lateral extensions or depth extensions or large-scale step-out drilling). |
Having recently completed an OPFS, the Company is working towards completing a definitive feasibility study. |
|
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 diagrams disclosed previous releases. These are accessible on the Company’s website as discussed above. |
#GRX GreenX Metals LTD – Acquiring Large Scale Copper Project in Germany
GREENX TO ACQUIRE LARGE SCALE SEDIMENT-HOSTED COPPER PROJECT IN CENTRAL GERMANY
GreenX Metals Limited (“GreenX” or “Company”) is pleased to advise that it has entered into an Earn-in Agreement through which GreenX can earn a 90% interest in Group 11 Exploration GmbH, a private German company which holds the Tannenberg exploration licence (“Project”) and is highly prospective for sediment-hosted (Kupferschiefer type) copper deposits.
The Project
· The Tannenberg exploration licence covers 272 km2 in the State of Hesse in central Germany, encompassing the historical “Richelsdorf” copper – silver mines.
· Prior to closure in the 1950’s, the Richelsdorf mines produced 416,500 t of copper and 33.7 Moz of silver from Kupferschiefer type deposits. These historic mines consisted of shallow underground workings originally accessed from surface outcrops.
· The Project also contains multiple drill intercepts over the high priority 14 km-long Richelsdorf Dome target, including:
o 2.1 m at 2.7% Cu and 48g/t Ag from 365.48 m; 1.5 m at 3.7% Cu and 33 g/t Ag from 209.50 m; 2.5 m at 1.8% Cu and 19 g/t Ag from 339.5 m in the southwest of the license area.
o 2.0 m at 1.6% Cu and 19 g/t Ag from 268 m in the north-east of the license area.
Figure 1: The Project is located in the industrial centre of Europe.
· Kupferschiefer style deposits are a well-known and prolific subtype of sediment-hosted copper deposit that:
o are the second most prevalent source of copper production and reserves in the world; and
o have been historically mined in Germany and are still mined in Poland where KGHM produced 592 kt of electrolytic copper in 2023.
· Excellent potential for new discoveries of shallow (50 m to 500 m), large scale and high grade Kupferschiefer style copper and silver mineralisation, with much of licence area remaining untested by modern exploration whereby thicker sections of footwall/ hanging wall mineralisation will be targeted.
· Modern understanding of Kupferschiefer mineralisation from prolific mining in Poland places new emphasis on hanging wall and footwall mineralisation, structural controls and metal zonation.
o In Polish Kupferschiefer mines, mineralisation typically forms within the Kupferschiefer shale and in strata up to 60 m below and 30 m above the shale. E.g., KGHM’s Rudna Mine in Poland, where footwall sandstone hosts 80% of the total copper resource, hanging wall limestone hosts 15%, and Kupferschiefer shale hosts only 5%.
GERMANY & EU MINING INDUSTRY
· Germany has been a significant mining jurisdiction in the past and continues its mining tradition, including:
o The K+S potash mines which operate 4 km away from the license area and are located in the State of Hesse.
o Anglo American are actively exploring the Löwenstern and Leine-Kupfer copper projects nearby. Löwenstern is 25 km away to the south in the German state of Thüringia, where drilling targeting the Kupferschiefer commenced in 2023. Leine-Kupfer was granted in January 2024 and is 60 km away to the north in the state of Lower Saxony.
o AMG Graphite operates a graphite mining and processing complex at Kropfmühl near Passau, Bavaria
o Vulcan Energy is successfully permitting lithium brine and geothermal power projects in the German states of Rheinland-Pfalz, Baden-Württemberg, and Hesse.
· Copper is a designated a Strategic Raw Material (“SRM”) under the EU’s Critical Raw Material Act, that entered into force on 23 May 2024. The CRMA signals the EU’s political commitment to strengthen EU supply of SRM’s (including copper) by giving the European Commission the power to designate Strategic Projects that will benefit from easier access to financing, expedited permitting processes and matchmaking with off-takers.
· The manufacturing sector, including the automotive, mechanical engineering, chemical and electrical industries, accounts for over 25% of Germany’s economic output, and 18% of GDP; these figures are significantly higher than in most other advanced economies
o The manufacturing sector provides 16% of national employment, some 8 million jobs, with mechanical engineering being the largest segment and dominated by SMEs.
o The automotive sector is a key industry and with around four million automobiles produced in 2023. Electric Vehicles are being adopted in Germany with numerous OEM’s investing in new production facilities and supply chains, such as Volkswagen’s Battery and Electric Drive production facilities and Tesla’s Berlin Gigafactory.
o Many of these industries are reliant on critical raw materials such as copper.
· German government recently announced creation of a EUR 1.1 billion (A$1.8 billion) investment fund to fortify Germany’s access to SRM’s (including copper) essential for high-tech and green projects. The fund will be managed by the state-owned KfW Development Bank.
GreenX Metals’ Chief Executive Officer, Mr Ben Stoikovich, commented:
“We are very excited to be adding the Tannenberg project to our exploration portfolio. Kupferschiefer style deposits are widely acknowledged as the most prolific source of modern-day copper production, with copper mining from the Polish Kupferschiefer deposits (KGHM) presently being Europe’s largest domestic source of strategic copper supply. We believe that Tanneberg has the potential to host large scale and high-grade copper deposits located in the heartland of German industry in the vicinity of major OEM’s such as Volkswagen’s Battery and Electric Drive production facilities and Tesla’s Berlin Gigafactory.
Copper is officially recognised by the EU as a strategic raw material for European industry and ongoing decarbonisation in Europe. This acquisition comes at a time when the German government and the EU have recently announced major policy initiatives to enhance security of supply of strategic raw materials such as copper by facilitating expedited permitting processes and access to project development funding. Germany, and in particular the State of Hesse, has a well-established mining industry with practical and efficient mine permitting processes. Furthermore, we anticipate increased political support for new copper projects in accordance with Germany’s Federal Ministry of Economic Affairs and Climate Action critical raw materials policies and the EU’s newly introduced Critical Raw Material Act.
Tannenberg is complementary to our Arctic Rift Copper project in Greenland and provides GreenX shareholders with enhanced exposure to strategic raw materials that are now a policy priority in both Germany and the wider EU. We are looking forward to updating shareholders over the coming months as we commence our exploration activities in Germany.”
Classification: 2.2 Inside Information
2.5 Total number of voting rights and capital
ENQUIRIES
|
Ben Stoikovich +44 207 478 3900
|
Sapan Ghai +44 207 478 3900
|
SUMMARY OF TERMS
GreenX has entered into an Earn-in Agreement (“Agreement”) through which GreenX can earn a 90% interest in Group 11 Exploration GmbH (“Group 11”). Key terms of the Agreement are as follows:
· GreenX to issue the vendor 500,000 fully paid ordinary shares (“Shares”) upfront.
· GreenX will fund a Work Program up to EUR 500,000 by 31 December 2025 (“Minimum Commitment”). The Work Program will be sufficient to satisfy requirements for the grant of an extension of the exploration license.
· Once the Minimum Commitment has been discharged, GreenX can elect to acquire 90% of the fully diluted share capital of Group 11 on or before 31 December 2025 in return for:
o GreenX paying A$3,000,000 to the vendor in Shares (based on the higher of the 10-day VWAP or A$0.30 per Share).
o The vendors’ 10% interest in Group 11 will then be free carried until completion of a feasibility study by Group 11 or GreenX.
o The Agreement also includes usual drag along and tag along rights, and an Area of Influence provision.
o Once GreenX has earned its 90% interest, the vendor may elect to exchange their remaining 10% interest in return for a 0.5% Net Smelter Royalty.
· If a Scoping Study is published by GreenX on the ASX regarding the license area or any area within the Area of Influence within 5 years of execution of the Agreement, GreenX will issue the vendor 5 million Shares on the completion of the first such Scoping Study.
· GreenX will act as the project manager.
Project Geology
Historical drilling and mine workings confirm the widespread presence of the crucial Kupferschiefer sequence within the Tannenberg licence (Figure 2). The sedimentary sequence forms a broad dome that outcrops near the centre of the licence area and extends down to approximately 500 m at the periphery (Figure 3). Regional and small-scale faults cut the licence area with the dominant orientation trending northwest-southeast, perpendicular to the Variscan Orogen. Zones of copper enrichment within the licence area correspond to fault intersections. Structure is a key targeting consideration at the Project.
Figure 2: The Kupferschiefer is gently folded to form the Richelsdorf Dome that extends from surface down to 500 m depth within the licence area. Historical mining around Richelsdorf exploited mineralisation near the surface. Historical drilling intercepted mineralised Kupferschiefer down to 436 m. Much of the Kupferschiefer between 50 to 500 m remains untested.
Figure 3: Interpreted cross-section through Tannenberg exploration licence with simplified stratigraphy. The historical Richelsdorf District is located at the apex of a large-scale anticline, the Richelsdorf Dome. The approximate extent of historical mining is shown. The cross-section passes between drill holes Ro23 and Ro45.
In the south of the licence area near the town of Ronshausen, drill holes intersected mineralised Kupferschiefer sequence at depths ranging from 211 to 368 m below the surface (e.g., Ro18 and Ro23). Near the town of Nentershausen in the north, an isolated drill hole intersected 2 m at 1.6% Cu (Ro45).
Table 1: Selected Drill Holes.
|
Locality |
Hole ID |
Intersect (m) |
Cu (%) |
||
|
From |
To |
Interval |
|||
|
Ronshausen |
Ro23 |
365.48 |
367.58 |
2.10 |
2.7 |
|
Ro18 |
209.50 |
211.00 |
1.50 |
3.7 |
|
|
Ro19 |
339.50 |
342.00 |
2.50 |
1.7 |
|
|
Ro15 |
285.86 |
289.31 |
3.45 |
1.0 |
|
|
Nentershausen |
Ro45 |
268.00 |
269.63 |
2.00 |
1.6 |
Historical exploration and sampling might have been too focussed on the Kupferschiefer shale horizon. For example, in Ro45, the isolated drill hit near Nentershausen, the last sample from the footwall assayed at 1% Cu (Figure 4). In bothRo45 and Ro23 shown in Figure 4, the historical sampling only covers one mineralised interval. Drilling at the Rudna Mining in Poland shows that copper mineralisation can occur in multiple intervals, above and below the Kupferschiefer shale.
Figure 4: Selected historical drill results from the Richelsdorf Dome target with comparison to drilling at the Rudna Mine, Poland. Sample coverage did not typically extend much above or below the shale unit.
Kupferschiefer copper deposits feature a distinct metal zonation pattern. The zonation transitions from iron, to copper, lead then zinc (Figure 5). Adjacent to every known copper deposit is the iron rich zone known as “Rote Fäule”, or “red rot” in English. Within the Tannenberg licence, a distinct zone of red rot has been identified in the south near Ronshausen. As well as the copper, historical drill core was also assayed for lead and zinc. This data will allow the Company to identify important metal zonations in the Project area.
|
Figure 5: Metal zonation pattern associated with Kupferschiefer type copper deposits. The zonation cuts across stratigraphy and progresses from iron to copper, lead, then zinc. Note: hem = hematite, cc = chalcocite, bo = bornite, cpy = chalcopyrite, ga = galena, sph = sphalerite, py = pyrite. Modified from Borg, 2017.
|
GreenX’s exploration hypothesis for the Project is that historical exploration was mainly based on an outdated deposit model that focussed on the 30-60 cm-thick Kupferschiefer shale horizon. Modern understanding of the Kupferschiefer deposit model now shows that up to 95% of mineable copper can be hosted in the footwall sandstone and hanging wall limestone.
Project History
Pre-industrial mining in central Germany dates back to the 12th Century. Copper was exploited from the Kupferschiefer in the Mansfield, Sangerhausen, and Richelsdorf mining districts. Most of the historical copper mining in central Germany was prior to the Industrial Revolution and well-before mechanised mining technology was widely available. Once surface accessible deposits were depleted, adits and shallow shafts were used to access deeper underground Kupferschiefer copper ores (Figure 6).
In the Richelsdorf district, historical production is estimated at 416,500 t of copper and 1,050 t (33.7 Moz) of silver. Production commenced in the 13th Century and ceased in 1955.
The Project area remains ostensibly undeveloped, comprised predominantly of small-holding farmland and woodland, since it was located in the Cold-War border zone between West and East Germany. During the Cold War (1947-1991), the Richelsdorf district sat within the strategically-important Fulda Gap. The Fulda Gap hosts two lowland corridors through which NATO military planners believed the Soviet Union could launch a land attack. The US military observation post “Romeo” was active at the Hesse-Thuringia border in the vicinity of the Project area during the Cold War and was only disbanded in 1991.
Between 1980 and 1987, St Joes Exploration GmbH (“St Joes Exploration”) were active in the region. St Joes Exploration’s drilling campaigns identified Kupferschiefer mineralisation near the towns of Ronshausen and Nentershausen (Appendix 1, Table 2).
The major mining activity in Hesse is potash mining operated by K+S Group, an international fertiliser company with production sites in Europe and North America. The major potash mining complex “Werra” has been operating for over 100 years and produces some 19 Mtpa of crude salt from underground workings between 700 – 1000m depth. K+S Group’s Werra plant is recognised as an important pillar for the economic and demographic development of the region.
In 2021, Anglo American’s ‘Kupfer Copper Germany GmbH’ (“Anglo”) began exploration activities in Thuringia, 25 km from the Tannenberg licence. There, historical drilling intercepted 0.5 m at 1.4% Cu from 761.9 m. Anglo initiated seismic, gravity, and magnetic surveys in 2021 and exploratory drilling in 2023.
Figure 6: Left: Underground extraction of the Kupferschiefer shale at the Wolfsberg mine in 1954. Miners laid on their sides to excavate the ore-bearing material. Right: Schematic of pre-industrial underground mining in Germany.
Modified from Zientek et al., 2015.
EU CrITICAl RAW MATERIAL ACT
On 23 May 2024, the EU’s Critical Raw Materials Act (“CRMA”), published as Regulation (EU) 2024/1252, entered into force following its adoption by the Council of the EU and European Parliament. The main objective of the CRMA is to maintain and establish a secure and sustainable supply of Critical Raw Materials to the EU. The CRMA lists Strategic Raw Materials (SRM’s), which are those most crucial for strategic technologies used for the green, digital, defence and aerospace applications. Copper is a designated a Strategic Raw Material (SRM’s) under the act
The CRMA sets benchmarks for domestic capacities along the strategic raw material supply chain and for diversifying EU supply by 2030:
· EU extraction capacity of at least 10% of the EU’s annual consumption of strategic raw materials;
· EU processing capacity of at least 40% of the EU’s annual consumption of strategic raw materials;
· EU recycling capacity of at least 25% of the EU’s annual consumption of strategic raw materials; and
· Not more than 65% of the Union’s annual consumption of each strategic raw material relies on a single third country for any relevant stage of the value chain.
The CRMA further demonstrates the EU’s political commitment to strengthening supply of SRM’s (including copper) by giving the European Commission the power to designate Strategic Projects that will benefit from easier access to financing, expedited permitting processes and matchmaking with off-takers.
In terms of permitting processes, under the CRMA EU Member States will be required to give priority to Strategic Projects in their administrative processes. The Act sets clear timelines for decisions to be taken on permitting applications linked to Strategic Projects. i.e., for Strategic Projects, the total duration of the permit granting process should not exceed 27 months for extraction projects or 15 months for processing and recycling projects.
To help companies through permitting, Member States are also required to designate single points of contact for critical raw materials projects. The single point of contact will provide guidance to project promoters on administrative issues and will serve as the sole contact point throughout the permit granting process.
Exploration Targeting Model
The Project is prospective for Kupferschiefer style copper-silver mineralisation. Kupferschiefer is a subtype of the sediment-hosted copper deposit model. Mineralisation typically forms around the Kupferschiefer shale, but is known to occur up to 60 m below and 30 m above the shale in Poland (Figure 7). In KGHM’s Rudna Mine in Poland, footwall sandstone hosts 80% of the total resource, hanging wall limestone hosts 15%, and Kupferschiefer shale hosts only 5%. Modern insights from mining the Kupferschiefer in Poland will be applied to our exploration strategy in Germany.
Figure 7: Comparison of current-day Kupferschiefer mining in Poland with historical mining in Germany.
Note: Modified from Zientek et al., 2015.
Historical mining and exploration in Germany mainly focussed on the Kupferschiefer shale unit (Figure 6 & 7). The Company’s exploration hypothesis is that as in Poland, significant footwall and hanging wall accumulations of Kupferschiefer copper are potentially present at the Project.
The historical thinking about Kupferschiefer deposits in Germany was that mineralisation was syngenetic with the sediments. Meaning that the copper was deposited at the same time as the shale. Accordingly, historical mining and exploration was highly focussed on the shale. Modern mining and research challenges the historical deposit model. In Poland, copper is being mined up to 60 m below and 30 m above the Kupferschiefer shale.
The modern understanding of Kupferschiefer mineralisation recognises epigenetic deposition. This means that the copper mineralisation came after the sediments were deposited (Figure 8). Modern Kupferschiefer mining recognises the importance of structures, metal zonation patterns, and footwall and hanging wall host rocks.
Figure 8: Deposit model of Kupferschiefer mineralisation and alteration. Note: Compared to pre-industrial times, copper mineralisation is now known to extend from the hanging wall limestone, through the Kupferschiefer shale, and well into the footwall sandstone. Source: Zientek et al., 2015.
Regional Geological Setting
The Project is hosted in the Southern Permian Basin (“SPB”) of Europe. The SPB is an intracontinental basin that developed on the northern foreland of the Variscan Orogen. Two Groups make up the SPB, the Rotliegend and the Zechstein (Figure 9). The Lower Rotliegend Group marks the boundary between the Permian and Carboniferous and is comprised of bi-modal volcanics with interbedded sedimentary rocks. After a 20- to 30-million-year-long- hiatus, the Upper Rotliegend Group was deposited towards the end of the Permian. The Upper Rotliegend Group strata transitions from terrestrial to a shallow marine environment.
The Zechstein Group formed in the late Permian when the Barents Sea flooded the continental SPB. The organic-rich reduced Kupferschiefer shale marks the base of the Zechstein Group. “Kupferschiefer” is German for “Copper Shale” and is also called “T1” by geologists. The shale is typically 30-60 cm thick but can also be missing from the stratigraphy.
Very high-grade copper mineralisation is generally associated with the Kupferschiefer shale unit. However, minable copper mineralisation also occurs in the footwall sandstone and hanging wall limestone units in Poland. Mineralisation can also be offset from the shale by up to 30 m above and 60 m below. Pre-industrial mining in Germany focussed on the high-grade but thin shale. Modern mining in Poland extracts copper from the footwall sandstone, shale, and hanging wall limestone. Mining intervals at the Rudna mine is 3 m on average but reach over 12 m in places.
Figure 9: Generalised Kupferschiefer stratigraphic sequence from Germany and Poland. Mineralisation can extend below and above the T1 shale. Source: Borg, 2017.
In Poland, copper deposits are hosted in the Fore-Sudetic Monocline, a sub-basin of the SPB. KGHM’s current mining operations take place over multiple adjacent deposits at depths ranging from 844 m to 1,385 m below ground. In 2023, KGHM’s Polish operations produced 592 kt of electrolytic copper and 1,403 t of silver (45.8 Moz).
Upcoming Work Programs
Future work programs at the Project will aid drill targeting. Initially, an in-country search for additional historical drilling and mining records will be undertaken. Geophysical methods such as seismic and magnetic surveys will be evaluated for their effectiveness in delineating subsurface structures at the high-priority Richelsdorf Dome target. Historical drill assays will be used to identify metal zonation patterns useful for exploration targeting. The area of primary interest covers 14 km-long stretch of the Richelsdorf Dome where Kupferschiefer strata outcrop at surface in the centre and extend down to approximately 500 m at the periphery.
A European based technical team will be assembled to manage exploration activities at the Project.
Risk Factors
Whilst GreenX has undertaken a due diligence process (including title and other risks) with respect to the Project, it should be noted that the usual risks associated with companies undertaking exploration and development activities of projects in Germany will remain at completion of the acquisition.
A number of additional risk factors specific to the Project and associated activities have also been identified, including, but not limited to:
(a) The Project is located in Germany, and as such, the operations of the Company will be exposed to related risks and uncertainties associated with the country, regional and local jurisdictions. Opposition to the Project, or changes in local community support for the Project, along with any changes in mining or investment policies or in political attitude in Germany and, in particular to the mining, processing or use of copper, may adversely affect the operations, delay or impact the approval process or conditions imposed, increase exploration and development costs, or reduce profitability of the Company.
(b) The Company’s exploration and any future mining activities are dependent upon the grant, maintenance and/or renewal from time to time of the appropriate title interests, licences, concessions, leases, claims, permits and regulatory consents which may be withdrawn or made subject to new limitations. Maintaining title interests or obtaining renewals of or getting the grant of title interests often depends on the Company being successful in obtaining and maintaining required statutory approvals for its proposed activities (including a licence for mining operations) and that the title interests, licences, concessions leases, claims, permits or regulatory consents it holds will be maintained and when required renewed.
There is no assurance that such title interests, licences, concessions, leases, claims, permits or regulatory consents will be granted, or even if granted, not be revoked, significantly altered or granted on terms or with conditions not acceptable to the Company, or not renewed to the detriment of the Company or that the renewals thereof will be successful.
Shareholders should note that some of the risks may be mitigated by the use of appropriate safeguards and systems, whilst others are outside the control of the Company and cannot be mitigated. Should any of the risks eventuate, then it may have a material adverse impact on the financial performance of the Project, the Company and the value of the Company’s securities.
TENEMENT INFORMATION
Table 2: Tenement information.
|
Licence Name |
Commodities |
Area (km2) |
Issue Date |
Expiry Date |
|
Tannenberg
|
1copper, silver 2antimony, arsenic, lead, gallium, germanium, gold, indium, cadmium, cobalt, molybdenum, nickel, palladium, platinum, rhodium, selenium, thallium, vanadium, bismuth, and zinc |
271.92 |
07.06.2022 |
07.06.2025 |
Notes
1 Target commodities
2 Commodities included in the licence
ISSUE OF SHARES
GreenX Metals Limited has today issued 600,000 Shares in relation to the Agreement.
An application will be made for admission of the Shares to the standard listing segment of the Official List of the FCA (Official List) and to trading on the main market of the London Stock Exchange for listed securities (LSE Admission). LSE Admission is expected to take place on or before 9 August 2024.
For the purposes of the Financial Conduct Authority’s Disclosure Guidance and Transparency Rules (DTRs), following LSE Admission, the Company’s issued ordinary share capital will be 279,501,032 ordinary shares. The above figure of 279,501,032 may be used by shareholders as the denominator for the calculations by which they can determine if they are required to notify their interest in, or a change to their interest in, the Company following LSE Admission
Following the issue of Shares, GreenX has the following securities on issue:
· 279,501,032 ordinary fully paid shares;
· 4,775,000 unlisted options exercisable at A$0.45 each on or before 30 November 2025;
· 5,525,000 unlisted options exercisable at A$0.55 each on or before 30 November 2026; and
· 11,000,000 performance rights that have an expiry date 8 October 2026.
-ENDS-
Competent Persons Statement
Information in this announcement that relates to Exploration Results is based on information compiled by Mr Thomas Woolrych, a Competent Person who is a Member of the Australian Institute of Mining and Metallurgy. Mr Woolrych is a Director Group 11 Exploration GmbH and will hold an indirect interest in GreenX shares and deferred consideration for the Project. Mr Woolrych 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 Reporting of Exploration Results, Mineral Resources and Ore Reserves’. Mr Woolrych consents to the inclusion in this announcement of the matters based on his information in the form and context in which it appears.
Forward Looking Statements
This release may include forward-looking statements, which may be identified by words such as “expects”, “anticipates”, “believes”, “projects”, “plans”, and similar expressions. These forward-looking statements are based on GreenX’s expectations and beliefs concerning future events. Forward looking statements are necessarily subject to risks, uncertainties and other factors, many of which are outside the control of GreenX, which could cause actual results to differ materially from such statements. There can be no assurance that forward-looking statements will prove to be correct. GreenX makes no undertaking to subsequently update or revise the forward-looking statements made in this release, to reflect the circumstances or events after the date of that release.
The information contained within this announcement is deemed by the Company to constitute inside information as stipulated under the Market Abuse Regulations (EU) No. 596/2014 as it forms part of UK domestic law by virtue of the European Union (Withdrawal) Act 2018 (‘MAR’). Upon the publication of this announcement via Regulatory Information Service (‘RIS’), this inside information is now considered to be in the public domain
1 Production numbers sourced from Zientek et al., 2015, Table 4.
Appendix 1: Exploration Results and JORC Tables
Table 1: Historical drill hole information
|
Hole ID |
Easting |
Northing |
Elevation (m MSL) |
Dip (°) |
Depth (m) |
Assay available |
|
Bebra-1 |
4346428 |
5649690 |
n/a |
90 |
n/a |
No |
|
C/77-B10 |
4353728 |
5660165 |
235 |
90 |
68.2 |
No |
|
Cornberg |
4349990 |
5658105 |
302 |
90 |
151.6 |
No |
|
Iba-1 |
4349160 |
5650548 |
n/a |
90 |
n/a |
No |
|
Iba-3 |
4349120 |
5649684 |
n/a |
90 |
n/a |
No |
|
Iba-4 |
4348366 |
5649523 |
n/a |
90 |
n/a |
No |
|
KB1 |
4356129 |
5659867 |
288.83 |
90 |
15 |
No |
|
Nesselroeden-1 |
4368324 |
5655767 |
252 |
90 |
193.7 |
No |
|
Obergude |
4339370 |
5662062 |
308.88 |
90 |
200.2 |
Yes |
|
Ro1 |
4349714 |
5649065 |
n/a |
90 |
n/a |
No |
|
Ro3 |
4348224 |
5648740 |
n/a |
90 |
n/a |
No |
|
Ro6 |
4348997 |
5648337 |
n/a |
90 |
n/a |
No |
|
Ro8 |
4348234 |
5648558 |
n/a |
90 |
n/a |
No |
|
Ro10 |
4347033 |
5647996 |
n/a |
90 |
n/a |
No |
|
Ro15 |
4348595 |
5647200 |
255 |
90 |
351 |
Yes |
|
Ro18 |
4348389 |
5647549 |
235 |
90 |
227 |
Yes |
|
Ro19 |
4349107 |
5647350 |
280 |
90 |
360.5 |
Yes |
|
Ro21 |
4348105 |
5647941 |
203 |
90 |
211 |
Yes |
|
Ro23 |
4347684 |
5647433 |
300 |
90 |
380 |
Yes |
|
Ro26 |
4347272 |
5647775 |
270 |
90 |
400 |
Yes |
|
Ro27 |
4346047 |
5649652 |
215 |
90 |
432 |
Yes |
|
Ro30 |
4347604 |
5647936 |
240 |
90 |
292.3 |
Yes |
|
Ro31 |
4346844 |
5651396 |
217 |
90 |
159.2 |
Yes |
|
Ro33 |
4347521 |
5648340 |
205 |
90 |
251.9 |
Yes |
|
Ro34 |
4347363 |
5651850 |
220 |
90 |
244.75 |
Yes |
|
Ro36 |
4347359 |
5650524 |
310 |
90 |
320.45 |
Yes |
|
Ro39 |
4358152 |
5656842 |
200 |
90 |
197.2 |
Yes |
|
Ro41 |
4346982 |
5647411 |
250 |
90 |
426.2 |
Yes |
|
Ro42 |
4348170 |
5647070 |
249 |
90 |
307 |
Yes |
|
Ro45 |
4356946 |
5656716 |
407 |
90 |
289 |
Yes |
|
Ro46 |
4358278 |
5658088 |
200 |
90 |
228 |
No |
Note: Coordinates are DHDN / 3-degree Gauss-Kruger zone 4.
Table 2: Historical drill hole assays
|
Hole ID |
Intersect (m) |
Cu (%) |
Ag (ppm) |
||
|
From |
To |
Interval |
|||
|
Ro15 |
285.857 |
286.018 |
0.161 |
0.532 |
10 |
|
Ro15 |
286.018 |
286.068 |
0.05 |
0.846 |
15 |
|
Ro15 |
286.068 |
286.243 |
0.175 |
0.72 |
13 |
|
Ro15 |
286.243 |
286.288 |
0.045 |
0.919 |
16 |
|
Ro15 |
286.288 |
286.388 |
0.1 |
0.638 |
12 |
|
Ro15 |
286.388 |
286.438 |
0.05 |
0.681 |
13 |
|
Ro15 |
286.438 |
286.532 |
0.094 |
0.59 |
12 |
|
Ro15 |
286.532 |
286.619 |
0.087 |
0.562 |
11 |
|
Ro15 |
286.619 |
286.695 |
0.076 |
0.64 |
12 |
|
Ro15 |
286.695 |
286.812 |
0.117 |
0.707 |
13 |
|
Ro15 |
286.812 |
286.942 |
0.13 |
0.811 |
13 |
|
Ro15 |
286.942 |
287.043 |
0.101 |
0.737 |
11 |
|
Ro15 |
287.043 |
287.17 |
0.127 |
1.6 |
21 |
|
Ro15 |
287.17 |
287.272 |
0.102 |
1.437 |
19 |
|
Ro15 |
287.272 |
287.372 |
0.1 |
0.835 |
13 |
|
Ro15 |
287.372 |
287.463 |
0.091 |
0.499 |
11 |
|
Ro15 |
288.021 |
288.093 |
0.072 |
0.313 |
4 |
|
Ro15 |
288.151 |
288.206 |
0.055 |
0.441 |
5 |
|
Ro15 |
288.206 |
288.261 |
0.055 |
0.651 |
5 |
|
Ro15 |
288.261 |
288.281 |
0.02 |
0.506 |
5 |
|
Ro15 |
288.281 |
288.323 |
0.042 |
0.642 |
6 |
|
Ro15 |
288.323 |
288.388 |
0.065 |
1.573 |
12 |
|
Ro15 |
288.388 |
288.472 |
0.084 |
4.708 |
28 |
|
Ro15 |
288.472 |
288.51 |
0.038 |
3.837 |
24 |
|
Ro15 |
288.559 |
288.588 |
0.029 |
8.823 |
57 |
|
Ro15 |
288.588 |
288.623 |
0.035 |
4.774 |
30 |
|
Ro15 |
288.623 |
288.651 |
0.028 |
4.382 |
32 |
|
Ro15 |
288.651 |
288.721 |
0.07 |
3.554 |
98 |
|
Ro15 |
288.721 |
288.763 |
0.042 |
3.511 |
32 |
|
Ro15 |
288.763 |
288.793 |
0.03 |
2.814 |
28 |
|
Ro15 |
288.793 |
288.823 |
0.03 |
1.573 |
11 |
|
Ro15 |
288.823 |
288.865 |
0.042 |
2.313 |
17 |
|
Ro15 |
288.865 |
288.883 |
0.018 |
0.567 |
7 |
|
Ro15 |
288.883 |
288.901 |
0.018 |
0.469 |
7 |
|
Ro15 |
288.901 |
288.972 |
0.071 |
0.645 |
10 |
|
Ro15 |
288.972 |
289.004 |
0.032 |
0.617 |
8 |
|
Ro15 |
289.004 |
289.057 |
0.053 |
0.641 |
9 |
|
Ro15 |
289.057 |
289.117 |
0.06 |
0.523 |
9 |
|
Ro15 |
289.117 |
289.129 |
0.012 |
0.349 |
0 |
|
Ro15 |
289.151 |
289.159 |
0.008 |
1.033 |
18 |
|
Ro15 |
289.159 |
289.169 |
0.01 |
0.641 |
14 |
|
Ro15 |
289.169 |
289.179 |
0.01 |
0.477 |
15 |
|
Ro15 |
289.179 |
289.235 |
0.056 |
0.817 |
10 |
|
Ro15 |
289.235 |
289.257 |
0.022 |
0.312 |
4 |
|
Ro15 |
289.257 |
289.312 |
0.055 |
0.321 |
4 |
|
Ro18 |
209.5 |
210 |
0.5 |
0.9 |
20 |
|
Ro18 |
210 |
210.25 |
0.25 |
7.2 |
70 |
|
Ro18 |
210.25 |
210.53 |
0.28 |
8.6 |
50 |
|
Ro18 |
210.53 |
210.76 |
0.23 |
3.3 |
35 |
|
Ro18 |
210.76 |
211 |
0.24 |
0.3 |
-2 |
|
Ro19 |
339.5 |
339.71 |
0.21 |
7.6 |
80 |
|
Ro19 |
339.71 |
340 |
0.29 |
2.5 |
30 |
|
Ro19 |
340 |
340.5 |
0.5 |
1.5 |
15 |
|
Ro19 |
340.5 |
341 |
0.5 |
1 |
10 |
|
Ro19 |
341 |
341.5 |
0.5 |
1.3 |
10 |
|
Ro19 |
341.5 |
342 |
0.5 |
0.43 |
10 |
|
Ro21 |
199 |
199.18 |
0.18 |
0.94 |
10 |
|
Ro21 |
199.18 |
199.4 |
0.22 |
0.49 |
6 |
|
Ro23 |
365.48 |
366 |
0.52 |
2 |
21 |
|
Ro23 |
366 |
366.45 |
0.45 |
0.88 |
17 |
|
Ro23 |
366.45 |
367 |
0.55 |
3.2 |
78 |
|
Ro23 |
367 |
367.49 |
0.49 |
5 |
80 |
|
Ro23 |
367.49 |
367.58 |
0.09 |
0.97 |
12 |
|
Ro26 |
388.3 |
388.48 |
0.18 |
2.1 |
|
|
Ro26 |
388.48 |
388.72 |
0.24 |
0.88 |
|
|
Ro26 |
388.72 |
389 |
0.28 |
0.74 |
|
|
Ro33 |
242.5 |
243.1 |
0.6 |
1.2 |
35 |
|
Ro33 |
243.1 |
243.5 |
0.4 |
0.31 |
10 |
|
Ro34 |
196.75 |
197 |
0.25 |
0.45 |
10 |
|
Ro41 |
414.35 |
414.85 |
0.5 |
0.45 |
10 |
|
Ro45 |
268 |
268.5 |
0.5 |
0.35 |
2 |
|
Ro45 |
268.5 |
269 |
0.5 |
2.3 |
25 |
|
Ro45 |
269 |
269.28 |
0.28 |
4.8 |
75 |
|
Ro45 |
269.28 |
269.63 |
0.35 |
0.59 |
3 |
|
Ro45 |
269.63 |
270 |
0.37 |
1 |
5 |
Note: Only assay results equal to or greater than 0.3% copper are reported.
JORC Code, 2012 Edition – Table 1 Report
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 (eg cut channels, random chips, or specific specialised industry standard measurement tools appropriate to the minerals under investigation, such as down hole gamma sondes, or handheld XRF instruments, etc). These examples should not be taken as limiting the broad meaning of sampling. |
Due to the historic nature of the drilling results reported herein, it is not possible to comment on the quality of the sampling used to produce the results described. It is known from historic reports that the drill core was sawn. Sampling of ¼ core was conducted during multiple exploration phases between 1980 and 1987 within the licence area by St Joes Exploration GmbH (“St Joes Exploration”). The information shown here was collated from scans of hard copy reports from that era and a State Survey Database. Assays, geological logging and gamma ray logs were conducted by St Joes Exploration. |
|
|
Include reference to measures taken to ensure sample representivity and the appropriate calibration of any measurement tools or systems used. |
No QAQC was reported. |
|
|
Aspects of the determination of mineralisation that are Material to the Public Report. In cases where ‘industry standard’ work has been done this would be relatively simple (eg ‘reverse circulation drilling was used to obtain 1 m samples from which 3 kg was pulverised to produce a 30 g charge for fire assay’). In other cases more explanation may be required, such as where there is coarse gold that has inherent sampling problems. Unusual commodities or mineralisation types (eg submarine nodules) may warrant disclosure of detailed information. |
Work was not conducted to modern industry standards. |
|
Drilling techniques |
Drill type (eg core, reverse circulation, open-hole hammer, rotary air blast, auger, Bangka, sonic, etc) and details (eg core diameter, triple or standard tube, depth of diamond tails, face-sampling bit or other type, whether core is oriented and if so, by what method, etc). |
St Joes Exploration · 10 cm drill cores were collected, further specifications are not known. State Survey Database · Unknown drilling techniques. |
|
Drill sample recovery |
Method of recording and assessing core and chip sample recoveries and results assessed.
|
Due to the historic nature of the drilling results reported herein, it is not possible to comment on the recoveries achieved at the time. |
|
|
Measures taken to maximise sample recovery and ensure representative nature of the samples. |
Not reported. |
|
|
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. |
Not reported. |
|
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. |
Information available is not appropriate for a Mineral Resource estimate. |
|
|
Whether logging is qualitative or quantitative in nature. Core (or costean, channel, etc) photography. |
Available logs are qualitative only. |
|
|
The total length and percentage of the relevant intersections logged. |
The entire hole was logged, the target zone is typically 2 m thick. |
|
Sub-sampling techniques |
If core, whether cut or sawn and whether quarter, half or all core taken. |
A reference to ¼ core is reported by St Joes Exploration however this is not specific to every hole/phase. |
|
and sample preparation |
If non-core, whether riffled, tube sampled, rotary split, etc and whether sampled wet or dry. |
N/A |
|
|
For all sample types, the nature, quality and appropriateness of the sample preparation technique. |
N/A |
|
|
Quality control procedures adopted for all sub-sampling stages to maximise representivity of samples. |
N/A
|
|
|
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. |
N/A |
|
|
Whether sample sizes are appropriate to the grain size of the material being sampled. |
N/A |
|
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. |
A St Joes Exploration reference reports that geochemical analysis was carried out by Robertson Research Ltd, Wales, however it is not specified if this was for each hole/phase. |
|
|
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. |
N/A |
|
|
Nature of quality control procedures adopted (eg standards, blanks, duplicates, external laboratory checks) and whether acceptable levels of accuracy (ie lack of bias) and precision have been established. |
N/A |
|
Verification of sampling and assaying |
The verification of significant intersections by either independent or alternative company personnel.
|
No verification carried out. |
|
|
The use of twinned holes. |
No twinned holes. |
|
|
Documentation of primary data, data entry procedures, data verification, data storage (physical and electronic) protocols. |
Limited data is available via hard copy reports. Data was digitised by Group 11 Exploration and merged with State/Federal databases. |
|
|
Discuss any adjustment to assay data. |
N/A |
|
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. |
Location accuracy is unknown. The location of holes drilled by St Joes Exploration comes from collar tables in historical reports. All other collar locations come from State/Federal databases. |
|
|
Specification of the grid system used. |
Latitude and Longitude in degree, minutes and seconds were provided by St Joes Exploration. All drill collar coordinates are reported here in the DHDN / 3-degree Gauss-Kruger zone 4 grid system. |
|
|
Quality and adequacy of topographic control. |
N/A |
|
Data spacing and distribution |
Data spacing for reporting of Exploration Results. |
Drillholes within the Ronshausen mineralised area are spaced between 400 – 700m. Outside of this area the drilling is sparce. |
|
|
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. |
Not sufficient for the establishment of a JORC compliant resource. |
|
|
Whether sample compositing has been applied. |
N/A |
|
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. |
The target Kupferschiefer layer is flat to slightly dipping, vertical drilling therefore intercepts at right angles and is appropriate. |
|
|
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. |
No sampling bias. |
|
Sample security |
The measures taken to ensure sample security. |
N/A |
|
Audits or reviews |
The results of any audits or reviews of sampling techniques and data. |
N/A |
Section 2 Reporting of Exploration Results
(Criteria 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 “Tannenberg” exploration licence is held 100% by Group 11 Exploration GmbH. The licence was granted on the 7th of June 2022 and is valid for 3 years. The licence is free from overriding royalties and native titles interests. There are historical mine workings within the licence area, but no known historical sites of cultural significance outside of mining. Within and surrounding the licence area, there are environmental protections zones with differing levels of protections. There are small areas identified as Natura 2000 Fauna Flora Habitat Areas and Bird Sanctuaries. Other environmental protection designated areas include Nature Reserves, National Natural Monuments, Landscape Protection Area, and Natural Parks. Based on due diligence and discussions with various stakeholders and consultants, the presence of environmental protection areas does not preclude exploration or eventual mining if conducted in accordance with applicable standards and regulations. The landform across the license area comprises mostly of farmland, forested areas, and small towns and villages. |
|
|
|
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 licence is in good standing. |
|
|
Exploration done by other parties |
Acknowledgment and appraisal of exploration by other parties. |
Exploration was carried out by St Joes Exploration (in JV with the Broken Hill Pty Co Ltd later BHP-Utah) between 1980 and 1987. Two projects were undertaken. The Richelsdorf project within the licence area as well as the Spessart-Rhoen project 85 km to the south. Hole IDs starting with ‘Ro’ were drilled by St Joes Exploration. All other drill holes come from State Survey databases with unknown history. Historical mining took place within the licence area. Mining activities ceased in the 1950’s. Comprehensive records of all mine workings are not available to the Company (and may not exist). |
|
|
Geology |
Deposit type, geological setting and style of mineralisation. |
Mineralisation is of the classic Kupferschiefer type (copper slate) within the Permian Zechstein Basin of Germany and Poland. The Zechstein Basin is hosted within the Southern Permian Basin (“SPB”) of Europe. The SPB is an intracontinental basin that developed on the northern foreland of the Variscan Orogen. Very high-grade copper mineralisation is generally associated with the Kupferschiefer shale unit. However, minable copper mineralisation also occurs in the footwall sandstone and hanging wall limestone units in Poland. Mineralisation can be offset from the shale by up to 30 m above and 60 m below. |
|
|
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: easting and northing of the drill hole collar elevation or RL (Reduced Level – elevation above sea level in metres) of the drill hole collar dip and azimuth of the hole down hole length and interception depth hole length. |
Appendix 1 contains all relevant drillhole information. |
|
|
|
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. |
All available drill collars are provided. The availability of historical assay results are listed in Appendix 1 Table 1. Assay results less than 0.3% Cu are not reported. |
|
|
Data aggregation methods |
In reporting Exploration Results, weighting averaging techniques, maximum and/or minimum grade truncations (eg cutting of high grades) and cut-off grades are usually Material and should be stated. |
N/A |
|
|
|
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. |
N/A |
|
|
|
The assumptions used for any reporting of metal equivalent values should be clearly stated. |
N/A |
|
|
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. |
Drilling is perpendicular to mineralisation. Detailed sampling was done to lithological contacts on a range of scales from 1-50cm. |
|
|
|
If it is not known and only the down hole lengths are reported, there should be a clear statement to this effect (eg ‘down hole length, true width not known’). |
Intercepts are true width. |
|
|
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. |
Appropriate diagrams, including a maps, cross sections, and tables are included in the main body of this announcement. |
|
|
Balanced reporting |
Where comprehensive reporting of all Exploration Results is not practicable, representative reporting of both low and high grades and/or widths should be practiced to avoid misleading reporting of Exploration Results. |
All available results are reported. Only assays above or equal to 0.4% Cu are reported for practical reasons. |
|
|
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. |
All substantive results are reported. Geological logs and downhole gamma logs are not reported here. |
|
|
Further work |
The nature and scale of planned further work (eg tests for lateral extensions or depth extensions or large-scale step-out drilling). |
Infill and step out drilling required to assess the full potential of mineralisation near Ronshausen is planned. The search for additional archive material and historical records will continue. Desktop analysis and drill targeting will be conducted in consultation with subject-matter experts. Geophysical methods (such as seismic, magnetic, electrical, and gravity) will be evaluated and used if deemed appropriate for the project. |
|
|
|
Diagrams clearly highlighting the areas of possible extensions, including the main geological interpretations and future drilling areas, provided this information is not commercially sensitive. |
These diagrams are included in the main body of this release. |
|