从海水反渗透(SWRO)盐水中高效回收锂的新型LiAlO2薄膜电极

U. Hafsa, Sifani Zavahir, Tasneem Elmakki, Zubair Ahmad, D. Han
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引用次数: 0

摘要

据报道,海水中的锂含量高达2300亿吨,但其浓度仅为0.17 ppm,太低了。因此,海水不是回收锂的实际来源;锂主要是通过太阳能干燥盐湖盐水(100- 200ppm的锂)提取的。盐湖盐水仅限于某一地区,世界上大部分地区都无法获得。然而,由于海水反渗透(SWRO)盐水在海水淡化技术中的广泛应用,它是一种相当广泛的资源。因此,本研究的重点是从SWRO浓盐水中提取锂。进料中的锂含量可提高到0.85 ppm,这似乎是一个有利的输入流。另一方面,与电容去离子和电渗析等其他当代技术相比,电开关离子交换(ESIX)在分离锂方面节能且经济。这些方法旨在显著缩短传统太阳能干燥过程所消耗的时间。密度泛函理论研究表明,与LMO和LiFePO4工作电极相比,新型LiAlO2工作电极可以更好地捕获ESIX系统中的锂。因此,本研究旨在定性和定量地评价ESIX方法在LiAlO2工作电极和活性炭反电极双电极配置下从高浓度SWRO盐水中回收锂的适用性。操作系统确认了锂的回收率,比能量消耗为100Wh/mol,纯度为97%,并且工作电极的可回收性至少在5次循环中没有任何明显的活性损失。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Facile and Novel LiAlO2 Film Electrodes for Energy Efficient Li recovery from Seawater Reverse Osmosis (SWRO) Brine
Concentration of Li in seawater is too low at 0.17 ppm despite its high content altogether with a reported 230 billion tons. Hence, seawater is not a practical source to recover Li from; Li is largely extracted by solar drying of salt-lake brines (100-200 ppm of Li). Salt-lake brines are confined to a certain region and not available for most parts of the world. However, seawater reverse osmosis (SWRO) brine is rather a widely available resource due to large adoption of the technique for water desalination. Hence, this study focuses on extraction of Li from concentrated SWRO brine. Li content in the feed can be increased up to 0.85 ppm, which is seemingly a favorable input stream. Electrically switched ion exchange (ESIX) on the other hand is energy efficient and economical in isolating Li, compared to other contemporary techniques such as capacitive deionization and electrodialysis. These approaches are meant to significantly shorten the time consumed in conventional solar drying process. Density functional theory studies have shown novel LiAlO2 type working electrode can be a better electrode to capture Li in ESIX system over widely known LMO and LiFePO4 working electrodes. Thus, this study intends to evaluate qualitatively and quantitatively the suitability of ESIX approach working in two electrodes configuration with LiAlO2 working electrode and activated carbon counter electrode to recover Li from concentrated SWRO brine. The operating system affirmed the recovery of Li with a specific energy consumption of 100Wh/mol and 97% purity, along with recyclability of the working electrode over minimum of 5 cycles without any apparent activity loss.
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