Tellurium and Selenium Cycling and Supply
Lead Research Organisation:
University of Aberdeen
Department Name: Geology and Petroleum Geology
Abstract
A shift from fossil fuels to low-CO2 technologies will lead to greater consumption of certain essential raw materials. Tellurium (Te) and selenium (Se) are 'E-tech' elements essential in photovoltaic (PV) solar panels. They are rare and mined only in small quantities; their location within the Earth is poorly known; recovering them is technically and economically challenging; and their recovery and recycling has significant environmental impacts. Yet demand is expected to surge and PV film production will consume most Se mined and outstrip Te supply by 2020. Presently, these elements are available only as by-products of Cu and Ni refining and their recovery from these ores is decreasing, leading to a supply risk that could hamper the roll-out of PV.
Meeting future demand requires new approaches, including a change from by-production to targeted processing of Se and Te-rich ores. Our research aims to tackle the security of supply by understanding the processes that govern how and where these elements are concentrated in the Earth's crust; and by enabling their recovery with minimal environmental and economic cost. This will involve >20 industrial partners from explorers, producers, processors, end-users and academia, contributing over £0.5M. Focussed objectives across 6 environments will target key knowledge gaps.
The magmatic environment: Develop methods for accurately measuring Se and Te in minerals and rocks - they typically occur in very low concentrations and research is hampered by the lack of reliable data. Experimentally determine how Te and Se distribute between sulfide liquids and magmas - needed to predict where they occur - and ground-truth these data using well-understood magmatic systems. Assess the recognised, but poorly understood, role of "alkaline" magmas in hydrothermal Te mineralisation.
The hydrothermal environment: Measure preferences of Te and Se for different minerals to predict mineral hosts and design ore process strategies. Model water-rock reaction in "alkaline" magma-related hydrothermal systems to test whether the known association is controlled by water chemistry.
The critical zone environment: Determine the chemical forms and distributions of Te and Se in the weathering environment to understand solubility, mobility and bioavailability. This in turn controls the geochemical halo for exploration and provides a natural analogue for microbiological extraction.
The sedimentary environment: Identify the geological and microbiological controls on the occurrence, mobility and concentration of Se and Te in coal - a possible major repository of Se. Identify the geological and microbiological mechanisms of Se and Te concentration in oxidised and reduced sediments - and evaluate these mechanisms as potential industrial separation processes.
Microbiological processing: Identify efficient Se- and Te-precipitating micro-organisms and optimise conditions for recovery from solution. Assess the potential to bio-recover Se and Te from ores and leachates and design a bioreactor.
Ionic liquid processing: Assess the ability of ionic solvents to dissolve Se and Te ore minerals as a recovery method. Optimise ionic liquid processing and give a pilot-plant demonstration.
This is the first holistic study of the Te and Se cycle through the Earth's crust, integrated with groundbreaking ore-processing research. Our results will be used by industry to: efficiently explore for new Te and Se deposits; adapt processing techniques to recover Te and Se from existing deposits; use new low-energy, low-environmental impact recovery technologies. Our results will be used by national agencies to improve estimates of future Te and Se supplies to end-users, who will benefit from increased confidence in security of supply, and to international government for planning future energy strategies. The public will benefit through unhindered development of sustainable environmental technologies to support a low-CO2 society.
Meeting future demand requires new approaches, including a change from by-production to targeted processing of Se and Te-rich ores. Our research aims to tackle the security of supply by understanding the processes that govern how and where these elements are concentrated in the Earth's crust; and by enabling their recovery with minimal environmental and economic cost. This will involve >20 industrial partners from explorers, producers, processors, end-users and academia, contributing over £0.5M. Focussed objectives across 6 environments will target key knowledge gaps.
The magmatic environment: Develop methods for accurately measuring Se and Te in minerals and rocks - they typically occur in very low concentrations and research is hampered by the lack of reliable data. Experimentally determine how Te and Se distribute between sulfide liquids and magmas - needed to predict where they occur - and ground-truth these data using well-understood magmatic systems. Assess the recognised, but poorly understood, role of "alkaline" magmas in hydrothermal Te mineralisation.
The hydrothermal environment: Measure preferences of Te and Se for different minerals to predict mineral hosts and design ore process strategies. Model water-rock reaction in "alkaline" magma-related hydrothermal systems to test whether the known association is controlled by water chemistry.
The critical zone environment: Determine the chemical forms and distributions of Te and Se in the weathering environment to understand solubility, mobility and bioavailability. This in turn controls the geochemical halo for exploration and provides a natural analogue for microbiological extraction.
The sedimentary environment: Identify the geological and microbiological controls on the occurrence, mobility and concentration of Se and Te in coal - a possible major repository of Se. Identify the geological and microbiological mechanisms of Se and Te concentration in oxidised and reduced sediments - and evaluate these mechanisms as potential industrial separation processes.
Microbiological processing: Identify efficient Se- and Te-precipitating micro-organisms and optimise conditions for recovery from solution. Assess the potential to bio-recover Se and Te from ores and leachates and design a bioreactor.
Ionic liquid processing: Assess the ability of ionic solvents to dissolve Se and Te ore minerals as a recovery method. Optimise ionic liquid processing and give a pilot-plant demonstration.
This is the first holistic study of the Te and Se cycle through the Earth's crust, integrated with groundbreaking ore-processing research. Our results will be used by industry to: efficiently explore for new Te and Se deposits; adapt processing techniques to recover Te and Se from existing deposits; use new low-energy, low-environmental impact recovery technologies. Our results will be used by national agencies to improve estimates of future Te and Se supplies to end-users, who will benefit from increased confidence in security of supply, and to international government for planning future energy strategies. The public will benefit through unhindered development of sustainable environmental technologies to support a low-CO2 society.
Planned Impact
We have fully engaged with stakeholders and beneficiaries from the outset, and used the catalyst stage to develop relationships with industrial, governmental and NGO partners. They have helped shape the research plan by exchange of knowledge, strategic plans, and problems. Key issues they raised have allowed us to identify knowledge gaps addressed in the Case for Support:
* Identification of potential resources (lack of data & predictive models)
* Low current value requires low cost production
* Lack of rapid analytical capability with the requisite detection limits
* Dependence on energy intensive smelting and refining of base metals as the dominant source of supply
* How to process alternative ores for recovery
* Lack of well understood mass flows in recovery operations, and thus a lack of optimisation
* Their deleterious role in the recovery of gold from ores
Our research covers four areas of impact outside the scientific community:
1 Identification and discovery of alternative sources of Se and Te. Beneficiaries will include BGS, USGS, Geological Survey of Cyprus and Geological Institute of Romania - NATIONAL AGENCIES with the responsibility to advise government on resource statistics and policy and to provide impartial advice to industry, academia and the public. Our research will enable them to provide improved Te and Se resource statistics and more realistic estimates of future supply to manufacturers, qualified by a sound understanding of the feasibility of extraction and processing. PRIVATE SECTOR COMPANIES who will benefit include those who are already mining Se and Te-rich material but with little understanding of the location of these elements in their deposits and how to recover them; and those actively exploring for new deposits that could include Se and/or Te as a co-product. Our partners include Platina, Vale, Glencore, AngloGold Ashanti and Scotgold. Our research will provide: a) data on the occurrence of Te and Se in crustal systems; b) data for companies to perform a cost-benefit analysis for recovery of Te and Se currently mined, and c) process-based predictive models for the efficient discovery of new economic deposits of Te and Se. One of our UK study sites is a SSSI owned by Leicester City Council and managed by Natural England. These PUBLIC SECTOR ORGANISATIONS will benefit through enhanced scientific understanding of the site, helping them promote its value to the general public.
2 Improved analytical and geometallurgical characterisation techniques. Beneficiaries will be PRIVATE SECTOR COMPANIES who are mining Se and/or Te bearing ore, including AngloGold Ashanti, Mandalay Resources, and Glencore, who will use our results to develop geometallurgical models for Se and Te to improve their recovery along with associated metals. Olympus will benefit through becoming a world-leader in the use of portable instruments for Te and Se determination in grade and mill control.
3 Environmentally benign, low-cost extraction techniques. This will benefit PRIVATE SECTOR COMPANIES who process ores, including partners 5NPlus, Mandalay Resources, AngloGold Ashanti and Scotgold. They will gain economic advantage through our research on new low-energy, low-environmental impact, locally-based extraction, demonstrated at pilot plant scale. The WIDER PUBLIC gain through continued access to, and reduced CO2 footprint of, modern technologies.
4 Strategic knowledge of security of supply. Beneficiaries will be GOVERNMENT AGENCIES who advise on resource strategy (BGS, SOPAC and especially through integration with USGS parallel programs), and POLICY MAKERS IN INTERNATIONAL GOVERNMENT planning future clean energy strategies. PRIVATE SECTOR end-users of Se and Te will benefit through improved integration of their supply chain, security of supply confidence, and direct contact with producers. The WIDER PUBLIC gain through development of sustainable environmental technologies to support a low-carbon society.
* Identification of potential resources (lack of data & predictive models)
* Low current value requires low cost production
* Lack of rapid analytical capability with the requisite detection limits
* Dependence on energy intensive smelting and refining of base metals as the dominant source of supply
* How to process alternative ores for recovery
* Lack of well understood mass flows in recovery operations, and thus a lack of optimisation
* Their deleterious role in the recovery of gold from ores
Our research covers four areas of impact outside the scientific community:
1 Identification and discovery of alternative sources of Se and Te. Beneficiaries will include BGS, USGS, Geological Survey of Cyprus and Geological Institute of Romania - NATIONAL AGENCIES with the responsibility to advise government on resource statistics and policy and to provide impartial advice to industry, academia and the public. Our research will enable them to provide improved Te and Se resource statistics and more realistic estimates of future supply to manufacturers, qualified by a sound understanding of the feasibility of extraction and processing. PRIVATE SECTOR COMPANIES who will benefit include those who are already mining Se and Te-rich material but with little understanding of the location of these elements in their deposits and how to recover them; and those actively exploring for new deposits that could include Se and/or Te as a co-product. Our partners include Platina, Vale, Glencore, AngloGold Ashanti and Scotgold. Our research will provide: a) data on the occurrence of Te and Se in crustal systems; b) data for companies to perform a cost-benefit analysis for recovery of Te and Se currently mined, and c) process-based predictive models for the efficient discovery of new economic deposits of Te and Se. One of our UK study sites is a SSSI owned by Leicester City Council and managed by Natural England. These PUBLIC SECTOR ORGANISATIONS will benefit through enhanced scientific understanding of the site, helping them promote its value to the general public.
2 Improved analytical and geometallurgical characterisation techniques. Beneficiaries will be PRIVATE SECTOR COMPANIES who are mining Se and/or Te bearing ore, including AngloGold Ashanti, Mandalay Resources, and Glencore, who will use our results to develop geometallurgical models for Se and Te to improve their recovery along with associated metals. Olympus will benefit through becoming a world-leader in the use of portable instruments for Te and Se determination in grade and mill control.
3 Environmentally benign, low-cost extraction techniques. This will benefit PRIVATE SECTOR COMPANIES who process ores, including partners 5NPlus, Mandalay Resources, AngloGold Ashanti and Scotgold. They will gain economic advantage through our research on new low-energy, low-environmental impact, locally-based extraction, demonstrated at pilot plant scale. The WIDER PUBLIC gain through continued access to, and reduced CO2 footprint of, modern technologies.
4 Strategic knowledge of security of supply. Beneficiaries will be GOVERNMENT AGENCIES who advise on resource strategy (BGS, SOPAC and especially through integration with USGS parallel programs), and POLICY MAKERS IN INTERNATIONAL GOVERNMENT planning future clean energy strategies. PRIVATE SECTOR end-users of Se and Te will benefit through improved integration of their supply chain, security of supply confidence, and direct contact with producers. The WIDER PUBLIC gain through development of sustainable environmental technologies to support a low-carbon society.
Organisations
People |
ORCID iD |
John Parnell (Principal Investigator) | |
Jorg Feldmann (Co-Investigator) |
Publications
Parnell J
(2019)
Variscan cycling of gold into a global coal reservoir
in Ore Geology Reviews
Armstrong J
(2023)
Trace element release from Bowland Shale into spring water in Lancashire
in Geological Society, London, Special Publications
Heptinstall E
(2023)
Trace element minerals from carbonatite-related fluids, The Aird, Scotland
in Scottish Journal of Geology
Parnell J
(2023)
The stable isotope (C, O, S) record of Paleoproterozoic marbles, Scotland
in Scottish Journal of Geology
Brolly C
(2021)
The sequestration of trace metals preserved in pyritized burrows
in Sedimentary Geology
Parnell J
(2016)
Selenium enrichment in Carboniferous Shales, Britain and Ireland: Problem or opportunity for shale gas extraction?
in Applied Geochemistry
Bullock L
(2018)
Selenium and tellurium concentrations of Carboniferous British coals
in Geological Journal
Parnell J
(2022)
Seawater signatures in the supracrustal Lewisian Complex, Scotland
in Geological Magazine
Spinks S
(2016)
Remobilization and mineralization of selenium-tellurium in metamorphosed red beds: Evidence from the Munster Basin, Ireland
in Ore Geology Reviews
McMahon S
(2018)
Reduction spheroids preserve a uranium isotope record of the ancient deep continental biosphere.
in Nature communications
Parnell J
(2021)
Niobium mineralization of sedimentary carbonates, Lewisian Complex, UK
in Applied Earth Science
Parnell J
(2019)
Neoproterozoic copper cycling, and the rise of metazoans
in Scientific Reports
Armstrong J
(2019)
Mobilisation of arsenic, selenium and uranium from Carboniferous black shales in west Ireland
in Applied Geochemistry
Parnell J
(2021)
Mixed metamorphic and fluid graphite deposition in Palaeoproterozoic supracrustal rocks of the Lewisian Complex, NW Scotland
in Terra Nova
Bullock L
(2019)
Mine-derived ochre precipitates: a potential selenium trap
in Applied Earth Science
Parnell J
(2016)
Metalliferous Biosignatures for Deep Subsurface Microbial Activity.
in Origins of life and evolution of the biosphere : the journal of the International Society for the Study of the Origin of Life
Parnell J
(2021)
Metal Flux from Dissolution of Iron Oxide Grain Coatings in Sandstones
in Geofluids
Parnell J
(2016)
Low-temperature concentration of tellurium and gold in continental red bed successions
in Terra Nova
Parnell J
(2018)
Liberation of selenium from alteration of the Bowland Shale Formation: evidence from the Mam Tor landslide
in Quarterly Journal of Engineering Geology and Hydrogeology
Armstrong J
(2020)
Kilometre-scale compartmentalization of fluid sources to a fossil hydrothermal system
in Ore Geology Reviews
Parnell J
(2021)
Increased biomass and carbon burial 2 billion years ago triggered mountain building
in Communications Earth & Environment
Bullock L
(2018)
High selenium in the Carboniferous Coal Measures of Northumberland, North East England
in International Journal of Coal Geology
Parnell J
(2021)
Graphite from Palaeoproterozoic enhanced carbon burial, and its metallogenic legacy
in Geological Magazine
Bullock L
(2020)
Gold in Irish Coal: Palaeo-Concentration from Metalliferous Groundwaters
in Minerals
Parnell J
(2015)
Gold in Devono-Carboniferous red beds of northern Britain
in Journal of the Geological Society
Parnell J
(2017)
Geochemistry and origin of organic-rich sediment veins in fractured granitic basement, Helmsdale, Sutherlandshire, UK
in Marine and Petroleum Geology
Carter L
(2019)
Exsolution depth and migration pathways of mineralising fluids in porphyry systems - examples from the Yerington District, Nevada
in Applied Earth Science
Baba M
(2019)
Emplacement of oil in the Devonian Weardale Granite of northern England
in Proceedings of the Yorkshire Geological Society
Parnell J
(2020)
Carbon in mineralized ultramafic intrusions, caledonides, northern Britain
in Lithos
Bullock L
(2019)
A thermal maturity map based on vitrinite reflectance of British coals
in Journal of the Geological Society
L. Bullock
(2019)
A thermal maturity map based on vitrinite reflectance of British coals
Parnell J
(2017)
A black shale protolith for gold-tellurium mineralisation in the Dalradian Supergroup (Neoproterozoic) of Britain and Ireland
in Applied Earth Science
Description | The range of Se and Te in British/Irish coals has been determined. Coal is not a viable resource of these elements. Bowland Shale in Britain and Ireland is anomalously rich in selenium. Processing of the Bowland Shale should be with care, to avoid release of toxic Se. Ochres from former coal and metal mining activity may contain anomalous enrichments of toxic Se, As and Tl. |
Exploitation Route | Relevant to search for resources of these elements Coal now ruled out as a realistic source. More understood about potential toxicity in the environment from these elements. |
Sectors | Chemicals Environment |
Description | Guidance for future extraction of trace elements using fungi. |
First Year Of Impact | 2019 |
Sector | Environment |
Impact Types | Societal |
Title | Data tables for carbon in global Palaeoproterozoic black shales |
Description | 4 tables, and accompanying references, from paper entitled 'Increased biomass and carbon burial 2 billion years ago triggered mountain building'. Tables record orogen depositional ages, deformation ages, Total Organic Carbon contents and organic carbon isotope compositions, for 20 orogens of Palaeoproterozoic age. |
Type Of Material | Database/Collection of data |
Year Produced | 2021 |
Provided To Others? | Yes |
URL | https://www2.bgs.ac.uk/nationalgeosciencedatacentre/citedData/catalogue/d10a1c96-55ff-4a35-be6b-92a4... |