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Engineering a Glass-Ceramic Solid Electrolyte Membrane for Reliable and Scalable Electrochemical Lithium Recycling Systems

Authors
Lee, HyungjunKim, JongwooLee, SeungwooKim, MinsungShin, Shun MyungJoo, Yong-YeonShin, Dong JuLee, DongseokChoi, BogeumKim, YoungsikPaik, UngyuSong, Taeseup
Issue Date
Nov-2025
Publisher
AMER CHEMICAL SOC
Keywords
lithium recycling; electrochemical system; solid electrolyte; melt-quenching; scalable fabrication
Citation
ACS Applied Energy Materials, v.8, no.21, pp 16256 - 16264
Pages
9
Indexed
SCIE
SCOPUS
Journal Title
ACS Applied Energy Materials
Volume
8
Number
21
Start Page
16256
End Page
16264
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/209247
DOI
10.1021/acsaem.5c02771
ISSN
2574-0962
2574-0962
Abstract
Lithium recycling technology has become increasingly important to address the growing demand for lithium-ion batteries (LIBs) and the limited availability of natural lithium resources. Among various approaches, the electrochemical lithium recycling system has emerged as a promising candidate due to its mild operating conditions and environmental compatibility. In this system, the solid electrolyte (SE) membrane plays a critical role by enabling selective lithium-ion transport while physically separating the electrode compartments. Therefore, SE membranes should possess high ionic conductivity and sufficient density to ensure a stable system operation. However, conventional sol-gel-derived SE membranes often suffer from incomplete densification, undermining the function of the membrane as a physical barrier. In this work, a high-density, high-conductivity lithium aluminum titanium phosphate (LATP)-based glass-ceramic SE membrane is developed via a melt-quenching approach. Optimization of quenching and crystallization conditions yields a SE membrane with a high relative density of 97.1% and an ionic conductivity of 5.06 x 10-4 S cm-1. The optimized SE membrane exhibits a dense microstructure that effectively suppresses liquid leakage and enables a stable electrochemical operation over 100 cycles. Additionally, a scalable bottom-up fabrication strategy based on glass powder processing is established. An integrated prismatic lithium recycling module, constructed by scaling up the SE membrane arrangement from a 1 x 1 to a 3 x 3 configuration and stacking multiple unit cells, yields an approximately 100-fold increase in the available current compared to the single-cell configuration, thereby enhancing the lithium recycling rate per unit time by 2 orders of magnitude.
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