Solar-enhanced lithium extraction with self-sustaining water recycling from salt-lake brines

环境科学 锂(药物) 萃取(化学) 太阳能 材料科学 环境工程 化学 化学工程 生态学 色谱法 生物 内分泌学 医学 工程类
作者
Qiancheng Xia,Zehui Deng,Siwei Sun,Wei Zhao,Jie Ding,Beidou Xi,Guandao Gao,Chao Wang
出处
期刊:Proceedings of the National Academy of Sciences of the United States of America [National Academy of Sciences]
卷期号:121 (23): e2400159121-e2400159121 被引量:76
标识
DOI:10.1073/pnas.2400159121
摘要

Lithium is an emerging strategic resource for modern energy transformation toward electrification and decarbonization. However, current mainstream direct lithium extraction technology via adsorption suffers from sluggish kinetics and intensive water usage, especially in arid/semiarid and cold salt-lake regions (natural land brines). Herein, an efficient proof-of-concept integrated solar microevaporator system is developed to realize synergetic solar-enhanced lithium recovery and water footprint management from hypersaline salt-lake brines. The 98% solar energy harvesting efficiency of the solar microevaporator system, elevating its local temperature, greatly promotes the endothermic Li + extraction process and solar steam generation. Benefiting from the photothermal effect, enhanced water flux, and enriched local Li + supply in nanoconfined space, a double-enhanced Li + recovery capacity was delivered (increase from 12.4 to 28.7 mg g −1 ) under one sun, and adsorption kinetics rate (saturated within 6 h) also reached twice of that at 280 K (salt-lake temperature). Additionally, the self-assembly rotation feature endows the microevaporator system with distinct self-cleaning desalination ability, achieving near 100% water recovery from hypersaline brines for further self-sufficient Li + elution. Outdoor comprehensive solar-powered experiment verified the feasibility of basically stable lithium recovery ability (>8 mg g −1 ) directly from natural hypersaline salt-lake brines with self-sustaining water recycling for Li + elution (440 m 3 water recovery per ton Li 2 CO 3 ). This work offers an integrated solution for sustainable lithium recovery with near zero water/carbon consumption toward carbon neutrality.
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