From arc magmas to ores (FAMOS): A mineral systems approach
Lead Research Organisation:
The Open University
Department Name: Faculty of Sci, Tech, Eng & Maths (STEM)
Abstract
Society is dependent on a reliable supply of metals and minerals for economic growth, improved standards of living, and development of infrastructure. Population growth means that even with increased recycling and resource efficiency, new mineral deposits still need to be discovered. The efficient exploration for, and discovery of, new resources requires new concepts and new tools.
The Mineral Systems approach to exploration considers ore deposits on a lithospheric scale, in terms of the "ingredients", processes and environments that favour their formation. This approach amounts to a "source-pathway-trap" model, with an increased emphasis on predictive capacity, rather than just feature recognition. Historically, much research has focused on the trap, and characterisation of the ore deposits themselves; here we aim to focus deeper in the system by integrating ore deposit formation with concepts of magmatism that arise from igneous petrology and volcanology. Therein lies a challenge because extant models for porphyry systems are increasingly at odds with magmatic models for crustal construction and arc volcanism. Rather than seeing magmatic systems in terms of large, liquid-rich magma chambers, emerging petrological models for crustal magmatism are turning instead to crystal-dominated, volatile-bearing "mushy" systems that traverse most or all of the crust. The dynamics of such systems have important consequences not just for arc magmatism, but also for the chemistry of the volatiles that are exsolved. These same volatiles fuel mineralisation and this is the synergy that we aim to exploit by assembling a multidisciplinary team of researchers from economic geology, igneous and metamorphic petrology, volcanology, geochemistry, numerical modelling and fluid dynamics. Our team embraces almost everyone currently engaged in porphyry mineralisation research in the UK and capitalises on strong existing links between UK ROs and the mining industry, many of who are Project Partners.
The research will involve analysis of minerals from a wide variety of mineralised and barren settings using a wealth of modern analytical tools that enable determination of an extensive suite of trace elements and isotope tracers. As each trace element responds to magmatic processes in subtly different ways due to the affinity of different elements for different phases (minerals, melts and fluids), so the multi-element approach affords many advantages over conventional proxies in which the full potential of the Periodic Table is not exploited. The analysis of natural systems will be underpinned by high pressure and temperature experiments to establish the phase relationships of ascending arc magmas and the partition coefficients that capture the affinities of elements for certain phases. As fluid accumulation and migration is an essential, but poorly understood, final step in ore deposit formation, we will develop, in tandem with the geochemistry, numerical models for fluid-bearing mushy systems. Finally, consideration will be given to critical metals that are passengers through the main ore-forming processes, but constitute important, often under-explored, by-products of porphyry mineralisation.
The research proposed has a strong element of blue skies investigation, but a particular focus on outcomes that will benefit industry through improved exploration tools. Thus the project bridges the divide between academic and applied research in a way that is not normally possible through industry-funded projects. This bridging activity lies at the heart of the Highlight Topic call, specifically through the integration of new advances in the study of mineral systems, igneous petrology and geochemistry, with a view to identifying conditions that can act as pathfinders for new targets. A key outcome will be a range of trace element proxies that will enable the mining industry to establish the potential fertility of a magmatic arc on local to regional scales.
The Mineral Systems approach to exploration considers ore deposits on a lithospheric scale, in terms of the "ingredients", processes and environments that favour their formation. This approach amounts to a "source-pathway-trap" model, with an increased emphasis on predictive capacity, rather than just feature recognition. Historically, much research has focused on the trap, and characterisation of the ore deposits themselves; here we aim to focus deeper in the system by integrating ore deposit formation with concepts of magmatism that arise from igneous petrology and volcanology. Therein lies a challenge because extant models for porphyry systems are increasingly at odds with magmatic models for crustal construction and arc volcanism. Rather than seeing magmatic systems in terms of large, liquid-rich magma chambers, emerging petrological models for crustal magmatism are turning instead to crystal-dominated, volatile-bearing "mushy" systems that traverse most or all of the crust. The dynamics of such systems have important consequences not just for arc magmatism, but also for the chemistry of the volatiles that are exsolved. These same volatiles fuel mineralisation and this is the synergy that we aim to exploit by assembling a multidisciplinary team of researchers from economic geology, igneous and metamorphic petrology, volcanology, geochemistry, numerical modelling and fluid dynamics. Our team embraces almost everyone currently engaged in porphyry mineralisation research in the UK and capitalises on strong existing links between UK ROs and the mining industry, many of who are Project Partners.
The research will involve analysis of minerals from a wide variety of mineralised and barren settings using a wealth of modern analytical tools that enable determination of an extensive suite of trace elements and isotope tracers. As each trace element responds to magmatic processes in subtly different ways due to the affinity of different elements for different phases (minerals, melts and fluids), so the multi-element approach affords many advantages over conventional proxies in which the full potential of the Periodic Table is not exploited. The analysis of natural systems will be underpinned by high pressure and temperature experiments to establish the phase relationships of ascending arc magmas and the partition coefficients that capture the affinities of elements for certain phases. As fluid accumulation and migration is an essential, but poorly understood, final step in ore deposit formation, we will develop, in tandem with the geochemistry, numerical models for fluid-bearing mushy systems. Finally, consideration will be given to critical metals that are passengers through the main ore-forming processes, but constitute important, often under-explored, by-products of porphyry mineralisation.
The research proposed has a strong element of blue skies investigation, but a particular focus on outcomes that will benefit industry through improved exploration tools. Thus the project bridges the divide between academic and applied research in a way that is not normally possible through industry-funded projects. This bridging activity lies at the heart of the Highlight Topic call, specifically through the integration of new advances in the study of mineral systems, igneous petrology and geochemistry, with a view to identifying conditions that can act as pathfinders for new targets. A key outcome will be a range of trace element proxies that will enable the mining industry to establish the potential fertility of a magmatic arc on local to regional scales.
Planned Impact
We have taken an "embedded impact" approach with FAMOS. Stakeholders and beneficiaries have been involved with the development of the project from its initiation (including the initial Highlight Topic suggestion). The scientific content of the proposal was developed in discussion with representatives from industry, and the final consortium has assembled an Advisory Board that includes industry representatives so as to maintain two-way knowledge exchange and ensure development of impact. We have also engaged an international set of project partners (PP) who will extend the reach of our impact (see letters of support). The embedded impact will be delivered through various activities to support outreach, engagement and dissemination.
The key impact goal for FAMOS is to improve discovery rates of porphyry deposits by aiding exploration under cover, influencing decision making in the exploration process, reducing exploration risk and reducing the environmental impacts of drilling and associated disruptive fieldwork through more efficient prospectivity assessment.
There are four impact objectives within FAMOS:
1) A revised Mineral Systems model of porphyry deposit formation. This will lead to improved targeting at regional and igneous complex scales and better inputs to national strategies on mineral resources. Beneficiaries include PRIVATE SECTOR COMPANIES involved in mining, exploration and consultancy (e.g. PPs Anglo American, Rio Tinto, BHPBilliton, Freeport McMoRan), and NATIONAL AGENCIES charged with encouraging exploration and developing strategic resources (e.g. BGS and PP USGS).
2) New proxies for porphyry fertility. This will provide low-cost tools and approaches that will support improved decision-making during exploration. By using multiple proxies within a single sample, more data-rich exploration is possible, and in turn less sampling is required and less environmental impact is caused. Beneficiaries will include PRIVATE SECTOR COMPANIES involved in exploration, consultancy, and the provision of data and analytical equipment to industry (i.e. service companies, e.g. see PPs Olympus, Zeiss and SRK ES letters of support).
3) E-tech elements in porphyries. We will generate vital data for better global and national e-tech resource estimation. This facilitates improved targeting for specific e-techs during exploration, and improved metallurgical characterisation of them. Beneficiaries will be GOVERNMENT AGENCIES who advise on resource strategy (e.g. BGS, PP USGS), and POLICY MAKERS IN GOVERNMENT planning future clean energy strategies. PRIVATE SECTOR COMPANIES exploring for resources (see PP Anglo American letter of support) and end-users of e-techs will benefit through improved strategic knowledge of future supplies and the WIDER PUBLIC will gain through support of sustainable environmental technologies for a low-carbon society.
4) Outreach, education and training. We have planned activities to increase public understanding of resource issues (discovery, depletion, environmental and social impacts, the 'e-tech' concept), particularly through NHM outreach, and activities to encourage the uptake of the new model and proxies with professional geoscientists through training workshops, short courses and engagement at high profile conferences. Beneficiaries include the WIDER PUBLIC, PRIVATE SECTOR COMPANIES as publicly traded bodies and employers of skilled professionals and PROFESSIONAL BODIES such as the IOM3 and Mineral Deposits Studies Group (see letter of support) who support training and professional development for their members.
The key impact goal for FAMOS is to improve discovery rates of porphyry deposits by aiding exploration under cover, influencing decision making in the exploration process, reducing exploration risk and reducing the environmental impacts of drilling and associated disruptive fieldwork through more efficient prospectivity assessment.
There are four impact objectives within FAMOS:
1) A revised Mineral Systems model of porphyry deposit formation. This will lead to improved targeting at regional and igneous complex scales and better inputs to national strategies on mineral resources. Beneficiaries include PRIVATE SECTOR COMPANIES involved in mining, exploration and consultancy (e.g. PPs Anglo American, Rio Tinto, BHPBilliton, Freeport McMoRan), and NATIONAL AGENCIES charged with encouraging exploration and developing strategic resources (e.g. BGS and PP USGS).
2) New proxies for porphyry fertility. This will provide low-cost tools and approaches that will support improved decision-making during exploration. By using multiple proxies within a single sample, more data-rich exploration is possible, and in turn less sampling is required and less environmental impact is caused. Beneficiaries will include PRIVATE SECTOR COMPANIES involved in exploration, consultancy, and the provision of data and analytical equipment to industry (i.e. service companies, e.g. see PPs Olympus, Zeiss and SRK ES letters of support).
3) E-tech elements in porphyries. We will generate vital data for better global and national e-tech resource estimation. This facilitates improved targeting for specific e-techs during exploration, and improved metallurgical characterisation of them. Beneficiaries will be GOVERNMENT AGENCIES who advise on resource strategy (e.g. BGS, PP USGS), and POLICY MAKERS IN GOVERNMENT planning future clean energy strategies. PRIVATE SECTOR COMPANIES exploring for resources (see PP Anglo American letter of support) and end-users of e-techs will benefit through improved strategic knowledge of future supplies and the WIDER PUBLIC will gain through support of sustainable environmental technologies for a low-carbon society.
4) Outreach, education and training. We have planned activities to increase public understanding of resource issues (discovery, depletion, environmental and social impacts, the 'e-tech' concept), particularly through NHM outreach, and activities to encourage the uptake of the new model and proxies with professional geoscientists through training workshops, short courses and engagement at high profile conferences. Beneficiaries include the WIDER PUBLIC, PRIVATE SECTOR COMPANIES as publicly traded bodies and employers of skilled professionals and PROFESSIONAL BODIES such as the IOM3 and Mineral Deposits Studies Group (see letter of support) who support training and professional development for their members.
People |
ORCID iD |
Frances Jenner (Principal Investigator) |
Publications
Mason E
(2024)
Chalcophile element degassing at an active continental arc volcano
in Geochimica et Cosmochimica Acta
Deng C
(2022)
The Influence of Ridge Subduction on the Geochemistry of Vanuatu Arc Magmas
in Journal of Geophysical Research: Solid Earth
Melekhova E
(2022)
Arc Crust Formation of Lesser Antilles Revealed by Crustal Xenoliths from Petit St. Vincent
in Journal of Petrology
Kunz B
(2022)
Critical metal enrichment in crustal melts: The role of metamorphic mica
in Geology
Iveson A
(2022)
Tracing Volatiles, Halogens, and Chalcophile Metals during Melt Evolution at the Tolbachik Monogenetic Field, Kamchatka
in Journal of Petrology
Deng C
(2022)
Effects of mantle flow on the chemistry of Coriolis Troughs backarc magmas
in Chemical Geology
Barber N
(2021)
Amphibole control on copper systematics in arcs: Insights from the analysis of global datasets
in Geochimica et Cosmochimica Acta
Wieser P
(2021)
Reconstructing Magma Storage Depths for the 2018 Ki¯lauean Eruption From Melt Inclusion CO 2 Contents: The Importance of Vapor Bubbles
in Geochemistry, Geophysics, Geosystems
Wieser P
(2021)
Encyclopedia of Geology
Cox D
(2020)
Elevated magma fluxes deliver high-Cu magmas to the upper crust
in Geology
Description | The results of the FAMOS grant have been used to place new constraints on the processes that contribute to the evolution of economically important ore deposits. This includes during similar processes, such as the partitioning of elements into fluids and gases that are released by during volcanic eruptions. |
Exploitation Route | Understanding the triggers for the enrichment of economically important concentrations of metals in the crust can be used to help predict which region of crust should be mined in the future. |
Sectors | Education Energy Environment Manufacturing including Industrial Biotechology Culture Heritage Museums and Collections Other |
Description | Research objectives in relation to industry applications and the wider relevance of resources (especially copper) to the green energy transition have been communicated to UK government science advisors, HM Treasury, and via a government POST secondment (Dan Smith). We are widening our public engagement interactions with a number of online presentations and webinars reaching up to several hundred participants in the industry and investment sectors worldwide. Scientific outputs from the grant are gaining increasing coverage in the popular press and industry magazines because of their relevance to the energy transition. |
First Year Of Impact | 2018 |
Sector | Government, Democracy and Justice,Culture, Heritage, Museums and Collections,Other |
Impact Types | Societal Policy & public services |
Title | Laser ablation ICP-MS of silver and selenium in melt inclusions |
Description | We developed the new capability to analyse selenium and silver in melt inclusions that are 50 microns in size (and larger) using laser ablation ICP-MS. |
Type Of Material | Improvements to research infrastructure |
Year Produced | 2020 |
Provided To Others? | Yes |
Impact | This new capability allowed us to demonstrate that selenium partitions into fluids during shallow crustal processes and during subaerial eruptions. This finding will aid in the understanding of the toxic hazards associated with volcanic eruptions and the evolution of ore deposits in the crust. |
URL | https://www.sciencedirect.com/user/identity/landing?code=t7Lu0ftPHAXFtJ4aPx5x3P92LyL6INfa2iB8NnFU&st... |
Description | BHP |
Organisation | BHP Billiton |
Country | Australia |
Sector | Private |
PI Contribution | Presented initial project results to representatives from BHP in May and November 2018, highlighting industry-relevant aspects. |
Collaborator Contribution | BHP agreed to open up project results from two PhD projects they are supporting and provide access to samples from several of their operations. |
Impact | None |
Start Year | 2018 |
Description | Barbara Kunz spoke about the FAMOS project at Soapbox Science |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Geographic Reach | Regional |
Primary Audience | Public/other audiences |
Results and Impact | Dr Barbara Kunz, research project officer working in the geochemistry lab of the School of Environment, Earth and Ecosystem Sciences at the Open University (OU) spoke about the FAMOS project at Soapbox Science, Milton Keynes in June 2019. Soapbox Science is a novel public outreach platform for promoting women scientists and the science they do. |
Year(s) Of Engagement Activity | 2019 |
URL | http://soapboxscience.org |
Description | Science-a-thon |
Form Of Engagement Activity | Engagement focused website, blog or social media channel |
Part Of Official Scheme? | No |
Geographic Reach | International |
Primary Audience | Public/other audiences |
Results and Impact | A series of images & short caption on Twitter about about Barbara Kunz's day of science, to show what day to day science looks likes. |
Year(s) Of Engagement Activity | 2019 |