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Electrosorption Theoretically Outperforms Nanofiltration and Electrodialysis for Direct Lithium Extraction from Brines

Rui Wang, Meng Sheng, Xitong Liu, Qiaoying Wang, Zhiwei Wang, Li Wang

2025Environmental Science & Technology6 citationsDOI

Abstract

The demand for lithium (Li) is rapidly growing as Li-ion batteries play an increasingly important role in achieving the global “net-zero emissions”. Direct lithium extraction (DLE) technologies have emerged as a transformative technology for efficiently and sustainably producing Li products from brine. While numerous studies have focused on improving Li + /Mg 2+ selectivity, proper Li + concentration before carbonation is largely overlooked. In this critical review, we examine the critical performance requirements for DLE, focusing on active-control DLE technologies where external fields actively regulate extraction, including nanofiltration, electrodialysis, and electrosorption. Although all three technologies can achieve high Li + /Mg 2+ selectivity with the development of advanced materials, electrodialysis and electrosorption are capable of simultaneously separating and concentrating Li +, making them more promising for realizing a real DLE process compared to nanofiltration. Furthermore, we compare the economic and environmental performance of these technologies. While the levelized cost of lithium carbonate for electrosorption (5,400 USD ton –1 ) is comparable to nanofiltration and electrodialysis, its global warming potential (−3911 kg CO 2 eq) is markedly lower. Thus, electrosorption theoretically emerges as the most promising candidate for achieving a truly environmentally sustainable DLE process. Finally, we discuss the key challenges to industrial deployment of ES and outline potential strategies for their resolution.

Topics & Concepts

ElectrodialysisNanofiltrationProcess engineeringCarbonationEnvironmental scienceSustainabilityLithium (medication)Extraction (chemistry)Software deploymentMembrane technologyComputer scienceBiochemical engineeringChemistryProcess (computing)Transformative learningSustainable developmentLife-cycle assessmentMaterials scienceEnvironmental engineeringGlobal-warming potentialNanotechnologyWaste managementPulp and paper industryCost of electricity by sourceEmerging technologiesExtraction and Separation ProcessesMembrane-based Ion Separation TechniquesMembrane Separation Technologies
Electrosorption Theoretically Outperforms Nanofiltration and Electrodialysis for Direct Lithium Extraction from Brines | Litcius