Decarbonisation to drive dramatic increase in mining waste–Options for reduction
暂无分享,去创建一个
S. Micklethwaite | M. Yahyaei | K. Runge | D. Franks | R. Valenta | A. Parbhakar-Fox | É. Lèbre | J. Segura-Salazar | V. Jokovic | I. Verster | M. Stringer | E. Savinova | Christian Antonio | Anita Parbhakar-Fox
[1] Ruilian Zhang,et al. Energy transition minerals and their intersection with land-connected peoples , 2022, Nature Sustainability.
[2] Shi-chang Kang,et al. A green and efficient technology to recover rare earth elements from weathering crusts , 2022, Nature Sustainability.
[3] J. Steen,et al. A unified metric for costing tailings dams and the consequences for tailings management , 2022, Resources Policy.
[4] Dieison M da Silva,et al. An update on global mining land use , 2022, Scientific data.
[5] R. Rodríguez-Pacheco,et al. Experimental study of efflorescence salt crusts formation in tailings dams: Possibility of metal recovery , 2022, Minerals Engineering.
[6] N. T. Nassar,et al. Rock-to-Metal Ratio: A Foundational Metric for Understanding Mine Wastes , 2022, Environmental science & technology.
[7] E. Forbes,et al. Review on advances in mineral processing technologies suitable for critical metal recovery from mining and processing wastes , 2022, Cleaner Engineering and Technology.
[8] S. Pfister,et al. Regionalized Life Cycle Inventories of Global Sulfidic Copper Tailings. , 2022, Environmental science & technology.
[9] J. Owen,et al. Complex orebodies and future global metal supply: An introduction , 2022, Resources Policy.
[10] Xiaoyu Yan,et al. Towards sustainable extraction of technology materials through integrated approaches , 2021, Nature Reviews Earth & Environment.
[11] S. C. Chelgani,et al. Systematic characterization of historical tailings for possible remediation and recovery of critical metals and minerals – The Yxsjöberg case , 2021, Journal of Geochemical Exploration.
[12] H. Prommer,et al. Toward a more sustainable mining future with electrokinetic in situ leaching , 2021, Science Advances.
[13] Sara Bjørn Aaen,et al. Social no-go factors in mine site selection , 2021, The Extractive Industries and Society.
[14] J. Owen,et al. Global Scan of Disruptions to the Mine Life Cycle: Price, Ownership, and Local Impact. , 2021, Environmental science & technology.
[15] Martin Stringer,et al. Tailings facility disclosures reveal stability risks , 2021, Scientific reports.
[16] H. Sverdrup,et al. Modelling Global Nickel Mining, Supply, Recycling, Stocks-in-Use and Price Under Different Resources and Demand Assumptions for 1850–2200 , 2021, Mining, Metallurgy & Exploration.
[17] B. Dold. Sourcing of critical elements and industrial minerals from mine waste – The final evolutionary step back to sustainability of humankind? , 2020 .
[18] J. Blais,et al. Recovery potential of rare earth elements from mining and industrial residues: A review and cases studies , 2020 .
[19] M. Caraballo,et al. Revalorization of Haveri Au-Cu mine tailings (SW Finland) for potential reprocessing , 2020 .
[20] B. P. Wilson,et al. Glycine leaching of Sarcheshmeh chalcopyrite concentrate at high pulp densities in a stirred tank reactor , 2020 .
[21] J. Owen,et al. The social and environmental complexities of extracting energy transition metals , 2020, Nature Communications.
[22] D. Franks. Reclaiming the neglected minerals of development , 2020 .
[23] K. Nansai,et al. Review of critical metal dynamics to 2050 for 48 elements , 2020 .
[24] Gavin M. Mudd,et al. Global-scale remote sensing of mine areas and analysis of factors explaining their extent , 2020 .
[25] J. Eksteen,et al. Leaching and ion exchange based recovery of nickel and cobalt from a low grade, serpentine-rich sulfide ore using an alkaline glycine lixiviant system , 2020 .
[26] D. Kemp,et al. Catastrophic tailings dam failures and disaster risk disclosure , 2020 .
[27] H. Sverdrup,et al. On the long-term sustainability of copper, zinc and lead supply, using a system dynamics model , 2019 .
[28] Luís Marcelo Tavares,et al. Life Cycle Assessment in the minerals industry: Current practice, harmonization efforts, and potential improvement through the integration with process simulation , 2019, Journal of Cleaner Production.
[29] Shahjadi Hisan Farjana,et al. A review on the impact of mining and mineral processing industries through life cycle assessment , 2019, Journal of Cleaner Production.
[30] Robben,et al. Sensor‐Based Ore Sorting Technology in Mining—Past, Present and Future , 2019, Minerals.
[31] A. Karrech,et al. Gold extraction from paleochannel ores using an aerated alkaline glycine lixiviant for consideration in heap and in-situ leaching applications , 2019, Minerals Engineering.
[32] C. Petter,et al. Pre-concentration potential evaluation for a silicate zinc ore by density and sensor-based sorting methods , 2019, REM - International Engineering Journal.
[33] Joost Vervoort,et al. Bottom-up Initiatives and Participatory Approaches for Outlooks , 2019, Global Environment Outlook – GEO-6: Healthy Planet, Healthy People.
[34] G. Corder,et al. Re-thinking complex orebodies: Consequences for the future world supply of copper , 2019, Journal of Cleaner Production.
[35] Robert C. Bachus,et al. Why coal ash and tailings dam disasters occur , 2019, Science.
[36] J. Owen,et al. Displaced by mine waste: The social consequences of industrial risk-taking , 2019, The Extractive Industries and Society.
[37] Mifeng Gou,et al. Utilization of tailings in cement and concrete: A review , 2019, Science and Engineering of Composite Materials.
[38] A. Parbhakar-Fox,et al. A Geometallurgical Approach to Tailings Management: An Example from the Savage River Fe-Ore Mine, Western Tasmania , 2018, Minerals.
[39] M. Mankosa,et al. Improving coarse particle flotation using the HydroFloat™ (raising the trunk of the elephant curve) , 2018, Minerals Engineering.
[40] T. Tezuka,et al. Analysis of Potential for Critical Metal Resource Constraints in the International Energy Agency’s Long-Term Low-Carbon Energy Scenarios , 2018 .
[41] M. Aubertin,et al. In situ evaluation of performance of reclamation measures implemented on abandoned reactive tailings disposal site , 2018, Canadian Geotechnical Journal.
[42] E. Voet,et al. Assessing environmental implications associated with global copper demand and supply scenarios from 2010 to 2050 , 2018 .
[43] L. Ciacci,et al. Resource Demand Scenarios for the Major Metals. , 2018, Environmental science & technology.
[44] Xingqiang Song,et al. Comparative life cycle assessment of tailings management and energy scenarios for a copper ore mine: A case study in Northern Norway , 2017 .
[45] Michele Rosano,et al. Application of a life cycle assessment to compare environmental performance in coal mine tailings management. , 2017, Journal of environmental management.
[46] A. R. Batchelor,et al. Towards large scale microwave treatment of ores: Part 1 – Basis of design, construction and commissioning , 2017 .
[47] M. Hesse,et al. Increasing efficiency by selective comminution , 2017 .
[48] Maxim Seredkin,et al. In situ recovery, an alternative to conventional methods of mining: Exploration, resource estimation, environmental issues, project evaluation and economics , 2016 .
[49] F. Krausmann,et al. How Circular is the Global Economy?: An Assessment of Material Flows, Waste Production, and Recycling in the European Union and the World in 2005 , 2015 .
[50] S. Harrison,et al. A desulfurization flotation approach for the integrated management of sulfide wastes and acid rock drainage risks , 2015 .
[51] Nawshad Haque,et al. The greenhouse gas footprint of in-situ leaching of uranium, gold and copper in Australia , 2014 .
[52] Emmanuel Manlapig,et al. Designing mine tailings for better environmental, social and economic outcomes: a review of alternative approaches , 2014 .
[53] Geoffrey S. Simate,et al. Acid mine drainage: Challenges and opportunities , 2014 .
[54] Fengnian Shi,et al. Progress and Challenges in Electrical Comminution by High‐Voltage Pulses , 2014 .
[55] AubertinMichel,et al. Evaluation of a single-layer desulphurized tailings cover , 2013 .
[56] Zhehan Weng,et al. A Detailed Assessment of Global Cu Resource Trends and Endowments * , 2013 .
[57] S. Equeenuddin,et al. Current approaches for mitigating acid mine drainage. , 2013, Reviews of environmental contamination and toxicology.
[58] G. Mudd,et al. Lithium Resources and Production: Critical Assessment and Global Projections , 2012 .
[59] P. Crowson. Some observations on copper yields and ore grades , 2012 .
[60] J-P. Franzidis,et al. Mitigating acid rock drainage risks while recovering low-sulfur coal from ultrafine colliery wastes using froth flotation , 2012 .
[61] Michael Davies,et al. Filtered Dry Stacked Tailings - The Fundamentals , 2011 .
[62] J. L. Broadhurst,et al. Mitigating the generation of acid mine drainage from copper sulfide tailings impoundments in perpetuity: A case study for an integrated management strategy , 2010 .
[63] Michel Aubertin,et al. Life cycle assessment of mine tailings management in Canada , 2009 .
[64] Byung-Gon Ryu,et al. Electrolyte conditioning-enhanced electrokinetic remediation of arsenic-contaminated mine tailing. , 2009, Journal of hazardous materials.
[65] Bernhard Dold,et al. Sustainability in metal mining: from exploration, over processing to mine waste management , 2008 .
[66] G. Wilson,et al. Research of Co-Disposal of Tailings and Waste Rock , 2006 .
[67] M. Aubertin,et al. A laboratory study of covers made of low-sulphide tailings to prevent acid mine drainage , 2004 .
[68] M. Benzaazoua,et al. Physico-chemical properties of tailing slurries during environmental desulphurization by froth flotation , 2003 .
[69] P. Marion,et al. Environmental desulphurization of four Canadian mine tailings using froth flotation , 2000 .
[70] J. O. Leppinen,et al. Flotation in acid mine drainage control: Beneficiation of concentrate , 1997 .