Author
Listed:
- Gaofeng Wang
(Chinese Academy of Sciences
CAS Center for Excellence in Deep Earth Science
University of Chinese Academy of Sciences)
- Jie Xu
(Chinese Academy of Sciences
CAS Center for Excellence in Deep Earth Science
University of Chinese Academy of Sciences)
- Lingyu Ran
(Chinese Academy of Sciences
CAS Center for Excellence in Deep Earth Science
University of Chinese Academy of Sciences)
- Runliang Zhu
(Chinese Academy of Sciences
CAS Center for Excellence in Deep Earth Science
University of Chinese Academy of Sciences)
- Bowen Ling
(Chinese Academy of Sciences)
- Xiaoliang Liang
(Chinese Academy of Sciences
CAS Center for Excellence in Deep Earth Science
University of Chinese Academy of Sciences)
- Shichang Kang
(Chinese Academy of Sciences
CAS Center for Excellence in Deep Earth Science
University of Chinese Academy of Sciences)
- Yuanyuan Wang
(Chinese Academy of Sciences
CAS Center for Excellence in Deep Earth Science
University of Chinese Academy of Sciences)
- Jingming Wei
(Chinese Academy of Sciences
CAS Center for Excellence in Deep Earth Science
University of Chinese Academy of Sciences)
- Lingya Ma
(Chinese Academy of Sciences
CAS Center for Excellence in Deep Earth Science
University of Chinese Academy of Sciences)
- Yanfeng Zhuang
(Wuhan University)
- Jianxi Zhu
(Chinese Academy of Sciences
CAS Center for Excellence in Deep Earth Science
University of Chinese Academy of Sciences)
- Hongping He
(Chinese Academy of Sciences
CAS Center for Excellence in Deep Earth Science
University of Chinese Academy of Sciences)
Abstract
Heavy rare earth elements (HREEs) such as Gd–Lu, Sc and Y are irreplaceable metals for a number of critical (including clean) technologies, but they are scarce. Ion-adsorption deposits, which form within weathering crusts, supply more than 95% of the global HREE demand. However, these deposits are currently mined via ammonium-salt-based leaching techniques that are responsible for severe environmental damage and show low recovery efficiency. As a result, the adoption of such techniques is restricted for REE mining, further exacerbating REE scarcity, which in turn could lead to supply chain disruptions. Here we report the design of an innovative REE mining technique, electrokinetic mining (EKM), which enables green, efficient and selective recovery of REEs from weathering crusts. Its feasibility is demonstrated via bench-scale, scaled-up and on-site field experiments. Compared with conventional techniques, EKM achieves ~2.6 times higher recovery efficiency, an ~80% decrease in leaching agent usage and a ~70% reduction in metallic impurities in the obtained REEs. As an additional benefit, the results point to an autonomous purification mechanism for REE enrichment, wherein the separation process is based on the mobility and reactivity diversity between REEs and metallic impurities. Overall, the evidence presented suggests that EKM is a viable mining technique, revealing new paths for the sustainable harvesting of natural resources.
Suggested Citation
Gaofeng Wang & Jie Xu & Lingyu Ran & Runliang Zhu & Bowen Ling & Xiaoliang Liang & Shichang Kang & Yuanyuan Wang & Jingming Wei & Lingya Ma & Yanfeng Zhuang & Jianxi Zhu & Hongping He, 2023.
"A green and efficient technology to recover rare earth elements from weathering crusts,"
Nature Sustainability, Nature, vol. 6(1), pages 81-92, January.
Handle:
RePEc:nat:natsus:v:6:y:2023:i:1:d:10.1038_s41893-022-00989-3
DOI: 10.1038/s41893-022-00989-3
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Cited by:
- Yang, Xiaoming & Islam, Md. Monirul & Mentel, Grzegorz & Ahmad, Ashfaq & Vasa, László, 2024.
"Synergistic dynamics unveiled: Interplay between rare earth prices, clean energy innovations, and tech companies' market resilience amidst the Covid-19 pandemic and Russia-Ukraine conflict,"
Resources Policy, Elsevier, vol. 89(C).
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