Author:
Dugamin Elza J. M.,Richard Antonin,Cathelineau Michel,Boiron Marie-Christine,Despinois Frank,Brisset Anne
Abstract
AbstractElectric cars will require to increase the production of lithium dramatically (up to 2 Mtons lithium equivalent carbonate per year by 2030). However, conventional hard-rock and salar mining are facing environmental and social concerns. Therefore, alternative lithium resources may help meeting the global demand for the next decades. Here, we provide a systematic analysis of published lithium concentration in about 3000 samples of groundwater from 48 sedimentary basins worldwide. The highest lithium concentrations (> 102 mg l−1) are primarily found in high salinity waters (Total Dissolved Solids > 105 mg l−1) and are in the same range as brines from the most productive salars. Conservative estimations based on fluid volume and lithium concentration in selected reservoirs indicate that these lithium resources are comparable to salars and hard-rock mines (0.1–10 Mtons lithium). Therefore, lithium in groundwater from sedimentary basins could be a significant potential resource for the next decades.
Publisher
Springer Science and Business Media LLC
Reference50 articles.
1. U.S. Geological Survey. Mineral Commodity Summaries (U.S. Geological Survey, 2021).
2. Bibienne, T., Magnan, J.-F., Rupp, A. & Laroche, N. From mines to mind and mobiles: Society’s increasing dependence on lithium. Elements 16, 265–270 (2020).
3. Bradley, D. C. et al. Critical Mineral Resources of the United States—Economic and Environmental Geology and Prospects for Future Supply Ch. K (U.S. Geological Survey, 2017).
4. Romero, H., Mendez, M. & Smith, P. Mining development and environment injustice in the Atacama desert of Northern Chile. Environ. Justice 5, 70–76 (2012).
5. Hafner, M. & Tagliapietra, S. The Geopolitics of the Global Energy Transition (Springer, 2020).
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