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Impact of the establishment of US offshore wind power on neodymium flows

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  • Tomer Fishman

    (Yale University
    IDC Herzliya)

  • T. E. Graedel

    (Yale University)

Abstract

Wind power is often posed as a greenhouse gas emission mitigation option, yet from a global perspective, the constrained supplies of rare-earth metals required for large-scale offshore wind turbines seem increasingly likely to provide limits to offshore wind power and other rare-earth-metal applications in the coming years. A 2015 US Department of Energy study maps an ambitious roadmap for offshore wind power to be capable of meeting substantial US electric-generating capacity by 2050. Our study addresses the neodymium material requirements that would be needed. We find that regional differences in deployment schedules will result in complex patterns of new capacity additions occurring concomitantly with turbine retirements and replacement needs. These demands would total over 15.5 Gg (15.5 kt) of neodymium by 2050, of which 20% could potentially be avoided by circular usage from decommissioned turbines but only if recycling technologies are developed or, better still, magnets are designed for reuse. Because neodymium is deemed to be a ‘critical material’, these perspectives are vital information for the formation of policy related to wind-energy provisioning, to domestic production, and to the importation of the rare-earth elements that would be required.

Suggested Citation

  • Tomer Fishman & T. E. Graedel, 2019. "Impact of the establishment of US offshore wind power on neodymium flows," Nature Sustainability, Nature, vol. 2(4), pages 332-338, April.
    • Handle: RePEc:nat:natsus:v:2:y:2019:i:4:d:10.1038_s41893-019-0252-z
    DOI: 10.1038/s41893-019-0252-z
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    Cited by:

    1. Ren, Kaipeng & Tang, Xu & Wang, Peng & Willerström, Jakob & Höök, Mikael, 2021. "Bridging energy and metal sustainability: Insights from China’s wind power development up to 2050," Energy, Elsevier, vol. 227(C).
    2. Wang, Peng & Chen, Li-Yang & Ge, Jian-Ping & Cai, Wenjia & Chen, Wei-Qiang, 2019. "Incorporating critical material cycles into metal-energy nexus of China’s 2050 renewable transition," Applied Energy, Elsevier, vol. 253(C), pages 1-1.
    3. Liang, Yanan & Kleijn, René & van der Voet, Ester, 2023. "Increase in demand for critical materials under IEA Net-Zero emission by 2050 scenario," Applied Energy, Elsevier, vol. 346(C).
    4. Zhang, Haoran & Li, Ruixiong & Cai, Xingrui & Zheng, Chaoyue & Liu, Laibao & Liu, Maodian & Zhang, Qianru & Lin, Huiming & Chen, Long & Wang, Xuejun, 2022. "Do electricity flows hamper regional economic–environmental equity?," Applied Energy, Elsevier, vol. 326(C).
    5. Liang, Yanan & Kleijn, René & Tukker, Arnold & van der Voet, Ester, 2022. "Material requirements for low-carbon energy technologies: A quantitative review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 161(C).
    6. Chen, Jinyu & Luo, Qian & Tu, Yan & Ren, Xiaohang & Naderi, Niki, 2023. "Renewable energy transition and metal consumption: Dynamic evolution analysis based on transnational data," Resources Policy, Elsevier, vol. 85(PB).
    7. Ge, Zewen & Geng, Yong & Wei, Wendong & Zhong, Chen, 2022. "Assessing samarium resource efficiency in China: A dynamic material flow analysis," Resources Policy, Elsevier, vol. 76(C).
    8. Rao Fu & Kun Peng & Peng Wang & Honglin Zhong & Bin Chen & Pengfei Zhang & Yiyi Zhang & Dongyang Chen & Xi Liu & Kuishuang Feng & Jiashuo Li, 2023. "Tracing metal footprints via global renewable power value chains," Nature Communications, Nature, vol. 14(1), pages 1-14, December.
    9. Jan Streeck & Quirin Dammerer & Dominik Wiedenhofer & Fridolin Krausmann, 2021. "The role of socio‐economic material stocks for natural resource use in the United States of America from 1870 to 2100," Journal of Industrial Ecology, Yale University, vol. 25(6), pages 1486-1502, December.
    10. Li, Chen & Mogollón, José M. & Tukker, Arnold & Dong, Jianning & von Terzi, Dominic & Zhang, Chunbo & Steubing, Bernhard, 2022. "Future material requirements for global sustainable offshore wind energy development," Renewable and Sustainable Energy Reviews, Elsevier, vol. 164(C).
    11. Kun Peng & Kuishuang Feng & Bin Chen & Yuli Shan & Ning Zhang & Peng Wang & Kai Fang & Yanchao Bai & Xiaowei Zou & Wendong Wei & Xinyi Geng & Yiyi Zhang & Jiashuo Li, 2023. "The global power sector’s low-carbon transition may enhance sustainable development goal achievement," Nature Communications, Nature, vol. 14(1), pages 1-14, December.
    12. Bonfante, Mariele Canal & Raspini, Jéssica Prats & Fernandes, Ivan Belo & Fernandes, Suélen & Campos, Lucila M.S. & Alarcon, Orestes Estevam, 2021. "Achieving Sustainable Development Goals in rare earth magnets production: A review on state of the art and SWOT analysis," Renewable and Sustainable Energy Reviews, Elsevier, vol. 137(C).
    13. Anne P. M. Velenturf, 2021. "A Framework and Baseline for the Integration of a Sustainable Circular Economy in Offshore Wind," Energies, MDPI, vol. 14(17), pages 1-41, September.
    14. Venkataraman, Mahesh & Csereklyei, Zsuzsanna & Aisbett, Emma & Rahbari, Alireza & Jotzo, Frank & Lord, Michael & Pye, John, 2022. "Zero-carbon steel production: The opportunities and role for Australia," Energy Policy, Elsevier, vol. 163(C).

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