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Environmental Implications of Future Demand Scenarios for Metals: Methodology and Application to the Case of Seven Major Metals

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  • Ester Van der Voet
  • Lauran Van Oers
  • Miranda Verboon
  • Koen Kuipers

Abstract

In this paper, we develop a method to assess the environmental impacts of metal scenarios. The method is life cycle based, but enables forward looking and upscaling. The method aims at translating metal demand scenarios into technology‐specific supply scenarios, necessary to make the translation into environmental impacts. To illustrate the different steps of the methodology, we apply it to the case of seven major metals. Demand scenarios for seven major metals are taken from literature. We translate those into technology‐specific supply scenarios, and future time series of environmental impacts are specified including recycling rates, energy system transformation, efficiency improvement, and ore grade decline. We show that the method is applicable and may lead to relevant and, despite many uncertainties, fairly robust results. The projections show that the environmental impacts related to metal production are expected to increase steeply. Iron is responsible for the majority of impacts and emissions are relatively unaffected by changes in the production and energy system. For the other metals, the energy transition may have substantial benefits. By far, the most effective option for all metals appears to be to increase the share of secondary production. This would reduce emissions, but is expected to become effective only in the second half of the twenty‐first century. The circular economy agenda for metals is therefore a long‐term agenda, similar to climate change: Action must be taken soon while benefits will become apparent only at the long term.

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  • Ester Van der Voet & Lauran Van Oers & Miranda Verboon & Koen Kuipers, 2019. "Environmental Implications of Future Demand Scenarios for Metals: Methodology and Application to the Case of Seven Major Metals," Journal of Industrial Ecology, Yale University, vol. 23(1), pages 141-155, February.
    • Handle: RePEc:bla:inecol:v:23:y:2019:i:1:p:141-155
    DOI: 10.1111/jiec.12722
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    Cited by:

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    2. Philipp Schäfer & Mario Schmidt, 2021. "Model-based analysis of the limits of recycling for its contribution to climate change mitigation [Modellgestützte Analyse der Grenzen des Beitrags von Recycling zum Klimaschutz]," NachhaltigkeitsManagementForum | Sustainability Management Forum, Springer, vol. 29(2), pages 65-75, June.
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    6. Karan Bhuwalka & Randolph E. Kirchain & Elsa A. Olivetti & Richard Roth, 2023. "Quantifying the drivers of long‐term prices in materials supply chains," Journal of Industrial Ecology, Yale University, vol. 27(1), pages 141-154, February.
    7. Chris Kennedy & Reid Lifset, 2020. "Winners of the 2019 Graedel Prizes: The Journal of Industrial Ecology Best Paper Prizes," Journal of Industrial Ecology, Yale University, vol. 24(5), pages 940-942, October.
    8. Nils Thonemann & Anna Schulte & Daniel Maga, 2020. "How to Conduct Prospective Life Cycle Assessment for Emerging Technologies? A Systematic Review and Methodological Guidance," Sustainability, MDPI, vol. 12(3), pages 1-23, February.
    9. Talens Peiró, Laura & Martin, Nick & Villalba Méndez, Gara & Madrid-López, Cristina, 2022. "Integration of raw materials indicators of energy technologies into energy system models," Applied Energy, Elsevier, vol. 307(C).
    10. Christoph Helbig & Jonas Huether & Charlotte Joachimsthaler & Christian Lehmann & Simone Raatz & Andrea Thorenz & Martin Faulstich & Axel Tuma, 2022. "A terminology for downcycling," Journal of Industrial Ecology, Yale University, vol. 26(4), pages 1164-1174, August.
    11. Matthias Buyle & Amaryllis Audenaert & Pieter Billen & Katrien Boonen & Steven Van Passel, 2019. "The Future of Ex-Ante LCA? Lessons Learned and Practical Recommendations," Sustainability, MDPI, vol. 11(19), pages 1-24, October.
    12. Anastasiades, K. & Blom, J. & Buyle, M. & Audenaert, A., 2020. "Translating the circular economy to bridge construction: Lessons learnt from a critical literature review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 117(C).
    13. Karan Bhuwalka & Eunseo Choi & Elizabeth A. Moore & Richard Roth & Randolph E. Kirchain & Elsa A. Olivetti, 2023. "A hierarchical Bayesian regression model that reduces uncertainty in material demand predictions," Journal of Industrial Ecology, Yale University, vol. 27(1), pages 43-55, February.
    14. Jorge Torrubia & Alicia Valero & Antonio Valero & Anthony Lejuez, 2023. "Challenges and Opportunities for the Recovery of Critical Raw Materials from Electronic Waste: The Spanish Perspective," Sustainability, MDPI, vol. 15(2), pages 1-18, January.
    15. Xiaoyang Zhong & Mingming Hu & Sebastiaan Deetman & Bernhard Steubing & Hai Xiang Lin & Glenn Aguilar Hernandez & Carina Harpprecht & Chunbo Zhang & Arnold Tukker & Paul Behrens, 2021. "Global greenhouse gas emissions from residential and commercial building materials and mitigation strategies to 2060," Nature Communications, Nature, vol. 12(1), pages 1-10, December.
    16. Carlos de Castro & Iñigo Capellán-Pérez, 2020. "Standard, Point of Use, and Extended Energy Return on Energy Invested (EROI) from Comprehensive Material Requirements of Present Global Wind, Solar, and Hydro Power Technologies," Energies, MDPI, vol. 13(12), pages 1-43, June.

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