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A new copper frontier in Zambia’s emerging Central Province mineral corridor.
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418 km²
of continuous exploration ground, spanning 32 km north–south — a land package large enough to host multiple copper systems and support true district-scale discovery.
30 km
northeast of the Kitumba deposit acquired by Sinomine for US$560 million and advancing toward 60,000 tpa copper cathode production confirming the region's geological strength and commercial viability.
Tier 1
Geological potential positioned and situated on the most fertile margin of the Hook Batholith, where intrusive power, copper-rich metasediments, and major regional structures intersect.
OVERVIEW
Tier 1 Geology &
Strategic Proximity
Muli Copper Project
The Muli Copper Project sits within one of Zambia's most compelling growth corridors - a district where intrusive power, structural scale, and favourable geology come together to create a genuine tier-one exploration opportuniy.
Its 418 km² footprint occupies the most prospective structural and intrusive position in Zambia’s rising IOCG province — the type of geological setting that, historically, has delivered copper systems of global consequence.
For investors, Muli represents leverage to the future of copper — a forward-looking, high-quality opportunity underpinned by structural continuity, intrusive influence, and geological legitimacy.
As the world accelerates toward electrification and copper scarcity intensifies, Muli stands as a strategically positioned exploration asset with the potential to transform into a long-life copper platform.
The Muli Copper Project sits within one of Zambia's most compelling growth corridors - a district where intrusive power, structural scale, and favourable geology come together to create a genuine tier-one exploration opportuniy.
Its 418 km² footprint occupies the most prospective structural and intrusive position in Zambia’s rising IOCG province — the type of geological setting that, historically, has delivered copper systems of global consequence.
For investors, Muli represents leverage to the future of copper — a forward-looking, high-quality opportunity underpinned by structural continuity, intrusive influence, and geological legitimacy.
As the world accelerates toward electrification and copper scarcity intensifies, Muli stands as a strategically positioned exploration asset with the potential to transform into a long-life copper platform.
Muli Copper Project
A new copper frontier in Zambia’s emerging Central Province mineral corridor.
418 km²
of continuous exploration ground, spanning 32 km north–south — a land package large enough to host multiple copper systems and support true district-scale discovery.
30 km
northeast of the Kitumba deposit acquired by Sinomine for US$560 million and advancing toward 60,000 tpa copper cathode production confirming the region's geological strength and commercial viability.
Tier 1
Geological potential positioned and situated on the most fertile margin of the Hook Batholith, where intrusive power, copper-rich metasediments, and major regional structures intersect.
OVERVIEW
Tier 1 Geology &
Strategic Proximity
Muli Copper Project
The Muli Copper Project sits within one of Zambia's most compelling growth corridors - a district where intrusive power, structural scale, and favourable geology come together to create a genuine tier-one exploration opportuniy.
Its 418 km² footprint occupies the most prospective structural and intrusive position in Zambia’s rising IOCG province — the type of geological setting that, historically, has delivered copper systems of global consequence.
For investors, Muli represents leverage to the future of copper — a forward-looking, high-quality opportunity underpinned by structural continuity, intrusive influence, and geological legitimacy.
As the world accelerates toward electrification and copper scarcity intensifies, Muli stands as a strategically positioned exploration asset with the potential to transform into a long-life copper platform.
The Muli Copper Project sits within one of Zambia's most compelling growth corridors - a district where intrusive power, structural scale, and favourable geology come together to create a genuine tier-one exploration opportuniy.
Its 418 km² footprint occupies the most prospective structural and intrusive position in Zambia’s rising IOCG province — the type of geological setting that, historically, has delivered copper systems of global consequence.
For investors, Muli represents leverage to the future of copper — a forward-looking, high-quality opportunity underpinned by structural continuity, intrusive influence, and geological legitimacy.
As the world accelerates toward electrification and copper scarcity intensifies, Muli stands as a strategically positioned exploration asset with the potential to transform into a long-life copper platform.
Muli Copper Project
EXPLORATION APPROACH
The Path to
Discovery
Phased Exploration and Geological Evaluation
Our exploration strategy is built on momentum: map the system, pinpoint the opportunity, sharpen the picture, and strike where the geology converges. It’s how we move from raw potential to real discovery—deliberately, intelligently, and at pace.
This staged methodology is intended to reduce technical risk, preserve optionality, and ensure exploration decisions are made with clarity and discipline. By advancing from regional context to target-scale evaluation in measured steps, Makor seeks to deploy exploration capital efficiently while maintaining flexibility as new data is generated.
The first phase focuses on establishing a modern geological and geophysical baseline across the project. High-resolution magnetic and radiometric surveys, supported by satellite-based alteration mapping, will be used to identify major structures, intrusive signatures, and potential iron-oxide footprints characteristic of IOCG systems. This stage provides a foundational understanding of the project’s subsurface architecture and guides the prioritisation of early target areas.
Building on the remote-sensing results, the second phase moves into ground-based geochemical sampling and field mapping. Soil sampling grids, geological reconnaissance, and structural interpretation will refine the anomalies identified in Phase 1. This work helps delineate the shapes, trends, and scales of potential mineralised systems, narrowing broad geophysical features into defined zones of interest that warrant deeper investigation.
The third phase concentrates on advanced geophysics—such as induced polarisation (IP), electromagnetic surveys, or gravity methods—applied strategically to the most promising targets. These surveys help determine the depth, orientation, and continuity of conductive or dense bodies that may represent sulphides or alteration zones. By integrating these datasets, the team will generate well-supported drill targets with clear geological justification.
The final phase of the initial exploration cycle involves drill testing the highest-priority targets. Early drilling will focus on areas where structural corridors, intrusive contacts, and geophysical or geochemical anomalies converge. The objective is to confirm the presence of IOCG-style alteration and sulphide mineralisation at depth and establish vectors for follow-up drilling. This phase sets the stage for future resource definition and potential district-scale expansion.
The first phase focuses on establishing a modern geological and geophysical baseline across the project. High-resolution magnetic and radiometric surveys, supported by satellite-based alteration mapping, will be used to identify major structures, intrusive signatures, and potential iron-oxide footprints characteristic of IOCG systems. This stage provides a foundational understanding of the project’s subsurface architecture and guides the prioritisation of early target areas.
Building on the remote-sensing results, the second phase moves into ground-based geochemical sampling and field mapping. Soil sampling grids, geological reconnaissance, and structural interpretation will refine the anomalies identified in Phase 1. This work helps delineate the shapes, trends, and scales of potential mineralised systems, narrowing broad geophysical features into defined zones of interest that warrant deeper investigation.
The third phase concentrates on advanced geophysics—such as induced polarisation (IP), electromagnetic surveys, or gravity methods—applied strategically to the most promising targets. These surveys help determine the depth, orientation, and continuity of conductive or dense bodies that may represent sulphides or alteration zones. By integrating these datasets, the team will generate well-supported drill targets with clear geological justification.
The final phase of the initial exploration cycle involves drill testing the highest-priority targets. Early drilling will focus on areas where structural corridors, intrusive contacts, and geophysical or geochemical anomalies converge. The objective is to confirm the presence of IOCG-style alteration and sulphide mineralisation at depth and establish vectors for follow-up drilling. This phase sets the stage for future resource definition and potential district-scale expansion.
DISTRICT SCALE COPPER ASSET
Zambia's Next
Open-Pit Discovery
Systematic Copper Exposure Along a Proven Intrusive Margin
The geological setting is considered favourable for large-scale, intrusive-related copper systems, with regional structural architecture supportive of mineralising fluid flow. The scale of the landholding, limited historical exploration, and proximity to advancing copper developments and infrastructure support a systematic, district-scale exploration strategy.
Muli is a core component of Makor’s district-scale copper strategy, providing the scale, continuity, and optionality necessary to support systematic exploration and regional development planning. Within Makor’s ecosystem model, the project enhances portfolio depth and flexibility, positioning the company to respond effectively to long-term copper demand dynamics.
The geological setting is considered favourable for large-scale, intrusive-related copper systems, with regional structural architecture supportive of mineralising fluid flow. The scale of the landholding, limited historical exploration, and proximity to advancing copper developments and infrastructure support a systematic, district-scale exploration strategy.
Muli is a core component of Makor’s district-scale copper strategy, providing the scale, continuity, and optionality necessary to support systematic exploration and regional development planning. Within Makor’s ecosystem model, the project enhances portfolio depth and flexibility, positioning the company to respond effectively to long-term copper demand dynamics.
Systematic Copper Exposure Along a Proven Intrusive Margin
EXPLORATION APPROACH
The Path to
Discovery
Phased Exploration and Geological Evaluation
Our exploration strategy is built on momentum: map the system, pinpoint the opportunity, sharpen the picture, and strike where the geology converges. It’s how we move from raw potential to real discovery—deliberately, intelligently, and at pace.
This staged methodology is intended to reduce technical risk, preserve optionality, and ensure exploration decisions are made with clarity and discipline. By advancing from regional context to target-scale evaluation in measured steps, Makor seeks to deploy exploration capital efficiently while maintaining flexibility as new data is generated.
The first phase focuses on establishing a modern geological and geophysical baseline across the project. High-resolution magnetic and radiometric surveys, supported by satellite-based alteration mapping, will be used to identify major structures, intrusive signatures, and potential iron-oxide footprints characteristic of IOCG systems. This stage provides a foundational understanding of the project’s subsurface architecture and guides the prioritisation of early target areas.
Building on the remote-sensing results, the second phase moves into ground-based geochemical sampling and field mapping. Soil sampling grids, geological reconnaissance, and structural interpretation will refine the anomalies identified in Phase 1. This work helps delineate the shapes, trends, and scales of potential mineralised systems, narrowing broad geophysical features into defined zones of interest that warrant deeper investigation.
The third phase concentrates on advanced geophysics—such as induced polarisation (IP), electromagnetic surveys, or gravity methods—applied strategically to the most promising targets. These surveys help determine the depth, orientation, and continuity of conductive or dense bodies that may represent sulphides or alteration zones. By integrating these datasets, the team will generate well-supported drill targets with clear geological justification.
The final phase of the initial exploration cycle involves drill testing the highest-priority targets. Early drilling will focus on areas where structural corridors, intrusive contacts, and geophysical or geochemical anomalies converge. The objective is to confirm the presence of IOCG-style alteration and sulphide mineralisation at depth and establish vectors for follow-up drilling. This phase sets the stage for future resource definition and potential district-scale expansion.
The first phase focuses on establishing a modern geological and geophysical baseline across the project. High-resolution magnetic and radiometric surveys, supported by satellite-based alteration mapping, will be used to identify major structures, intrusive signatures, and potential iron-oxide footprints characteristic of IOCG systems. This stage provides a foundational understanding of the project’s subsurface architecture and guides the prioritisation of early target areas.
Building on the remote-sensing results, the second phase moves into ground-based geochemical sampling and field mapping. Soil sampling grids, geological reconnaissance, and structural interpretation will refine the anomalies identified in Phase 1. This work helps delineate the shapes, trends, and scales of potential mineralised systems, narrowing broad geophysical features into defined zones of interest that warrant deeper investigation.
The third phase concentrates on advanced geophysics—such as induced polarisation (IP), electromagnetic surveys, or gravity methods—applied strategically to the most promising targets. These surveys help determine the depth, orientation, and continuity of conductive or dense bodies that may represent sulphides or alteration zones. By integrating these datasets, the team will generate well-supported drill targets with clear geological justification.
The final phase of the initial exploration cycle involves drill testing the highest-priority targets. Early drilling will focus on areas where structural corridors, intrusive contacts, and geophysical or geochemical anomalies converge. The objective is to confirm the presence of IOCG-style alteration and sulphide mineralisation at depth and establish vectors for follow-up drilling. This phase sets the stage for future resource definition and potential district-scale expansion.
DISTRICT SCALE COPPER ASSET
Zambia's Next
Open-Pit Discovery
Systematic Copper Exposure Along a Proven Intrusive Margin
The geological setting is considered favourable for large-scale, intrusive-related copper systems, with regional structural architecture supportive of mineralising fluid flow. The scale of the landholding, limited historical exploration, and proximity to advancing copper developments and infrastructure support a systematic, district-scale exploration strategy.
Muli is a core component of Makor’s district-scale copper strategy, providing the scale, continuity, and optionality necessary to support systematic exploration and regional development planning. Within Makor’s ecosystem model, the project enhances portfolio depth and flexibility, positioning the company to respond effectively to long-term copper demand dynamics.
The geological setting is considered favourable for large-scale, intrusive-related copper systems, with regional structural architecture supportive of mineralising fluid flow. The scale of the landholding, limited historical exploration, and proximity to advancing copper developments and infrastructure support a systematic, district-scale exploration strategy.
Muli is a core component of Makor’s district-scale copper strategy, providing the scale, continuity, and optionality necessary to support systematic exploration and regional development planning. Within Makor’s ecosystem model, the project enhances portfolio depth and flexibility, positioning the company to respond effectively to long-term copper demand dynamics.
Systematic Copper Exposure Along a Proven Intrusive Margin
Zambia’s Next
Open-Pit Discovery
The Muli Copper Project combines geological strength, strategic positioning, and district-scale momentum. Sitting on an IOCG-fertile intrusive margin and close to the advancing Kitumba / Sinomine development, Muli is anchored in a proven copper neighbourhood. With a large, underexplored land position in Zambia’s next major copper corridor, it offers a rare first-mover opportunity supported by strong access, expanding infrastructure, and growing regional investment.
Zambia’s Next
Open-Pit Discovery
The Muli Copper Project combines geological strength, strategic positioning, and district-scale momentum. Sitting on an IOCG-fertile intrusive margin and close to the advancing Kitumba / Sinomine development, Muli is anchored in a proven copper neighbourhood. With a large, underexplored land position in Zambia’s next major copper corridor, it offers a rare first-mover opportunity supported by strong access, expanding infrastructure, and growing regional investment.