Issue 9, 2023

On the concentration polarisation in molten Li salts and borate-based Li ionic liquids

Abstract

Electrolytes that transport only Li ions play a crucial role in improving rapid charge and discharge properties in Li secondary batteries. Single Li-ion conduction can be achieved via liquid materials such as Li ionic liquids containing Li+ as the only cations because solvent-free fused Li salts do not polarise in electrochemical cells, owing to the absence of neutral solvents that allow polarisation in the salt concentration and the inevitably homogeneous density in the cells under anion-blocking conditions. However, we found that borate-based Li ionic liquids induce concentration polarisation in a Li/Li symmetric cell, which results in their transference (transport) numbers under anion-blocking conditions (tabcLi) being well below unity. The electrochemical polarisation of the borate-based Li ionic liquids was attributed to an equilibrium shift caused by exchangeable B–O coordination bonds in the anions to generate Li salts and borate-ester solvents at the electrode/electrolyte interface. By comparing borate-based Li ionic liquids containing different ligands, the B–O bond strength and extent of ligand exchange were found to be directly linked to the tabcLi values. This study confirms that the presence of dynamic exchangeable bonds causes electrochemical polarisation and provides a reference for the rational molecular design of Li ionic liquids aimed at achieving single-ion conducting liquid electrolytes.

Graphical abstract: On the concentration polarisation in molten Li salts and borate-based Li ionic liquids

Supplementary files

Article information

Article type
Paper
Submitted
07 Dec 2022
Accepted
30 Jan 2023
First published
31 Jan 2023

Phys. Chem. Chem. Phys., 2023,25, 6970-6978

Author version available

On the concentration polarisation in molten Li salts and borate-based Li ionic liquids

K. Shigenobu, F. Philippi, S. Tsuzuki, H. Kokubo, K. Dokko, M. Watanabe and K. Ueno, Phys. Chem. Chem. Phys., 2023, 25, 6970 DOI: 10.1039/D2CP05710G

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