浸出(土壤学)
锂(药物)
萃取(化学)
选矿
材料科学
铝
环境科学
产量(工程)
硅
冶金
矿物
废物管理
溶解
矿物酸
Mercury(编程语言)
土(古典元素)
易熔合金
电池(电)
氧化剂
可再生能源
工业废物
闪光灯(摄影)
废料
作者
Shichen Xu,Justin Sharp,Alexander Lathem,Qiming Liu,Lucas Eddy,Weiqiang Chen,Karla Silva,Shihui Chen,Bowen Li,Tengda Si,Jaeho Shin,Chi Hun Choi,Yimo Han,Kai Gong,Boris I. Yakobson,Yufeng Zhao,James M. Tour
出处
期刊:Science Advances
[American Association for the Advancement of Science]
日期:2025-10-03
卷期号:11 (40): eady6457-eady6457
被引量:6
标识
DOI:10.1126/sciadv.ady6457
摘要
Lithium (Li), the lowest-density metal, is an optimal element in most battery designs. With the increasing demand for Li, metallurgical techniques using excess acid leaching of mineral ores are common. However, these techniques are limited by multistep processes with adverse environmental impacts caused by secondary waste streams. Here, we show a one-step, acid-free, and alkali-free extraction process for Li from mineral ores with an initial Li content of only 4.8%. By applying flash Joule heating to α-spodumene under an atmosphere of Cl 2 (FJH-Cl 2 ), LiCl immediately distills from the remaining nonvolatile aluminum and silicon oxides. LiCl with a 97% purity and 94% yield can be achieved, enormously reducing costs and waste emissions. Local processing with FJH-Cl 2 can markedly lessen the complexity and cost of obtaining Li, obviating remote mining and facilitating the world’s progression toward cleaner renewable energies, which also paves the way for extracting critical metals from other mineral ores.
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