Understanding Lithium-ion Transport in Sulfolane- and Tetraglyme-Based Electrolytes Using Very Low-Frequency Impedance Spectroscopy  

作　　者：Janet SHo Oleg A.Borodin Michael SDing Lin Ma Marshall A.Schroeder Glenn R.Pastel Kang Xu 

机构地区：[1]Energy Sciences Division,Sensors and Electron Devices Directorate,US Army Research Laboratory,Adelphi MD 20783,USA

出　　处：《Energy & Environmental Materials》2023年第1期368-376,共9页能源与环境材料（英文）

基　　金：This work was supported by US Department of Army and the Joint Center for Energy Storage Research(JCESR),an Energy Innovation Hub funded by Depart-ment of Energy,Basic Energy Science,under an Interagency Agreement No.IAA SN202095.

摘　　要：With the increasing interest in highly concentrated electrolyte systems,correct determination of the cation transference number is important.Pulsed-field gradient NMR technique,which measures self-diffusion coefficients,is often applied on liquid electrolytes because of the wide accessibility and simple sample preparation.However,since the assumptions of this technique,that is,complete salt dissociation,all ions participating in motion,and all of them moving independently,no longer hold true in concentrated solutions,the transference numbers,thus obtained are often over-estimated.In the present work,impedance spectroscopy at a frequency range of 1 MHz to 0.1 mHz was used to examine the concentration effect on lithium-ion transference number under anion-blocking conditions T abc Liþfor two electrolytes:lithium bis(fluorosulfonyl)imide(LiFSI)in sulfolane(SL)and lithium bis(trifluorosulfonyl)imide(LiTFSI)in tetraglyme(G4).The T abc Liþof the former was almost an order of magnitude higher than that of the latter.It also appeared to increase with increasing concentration while the latter followed an opposite trend.The faster Li^(+)transport in the SL system is attributed to the formation of a liquid structure consisting of extended chains/bridges of SL molecules and the anions,which facilitate a cation-hopping/ligand-exchanged-typed diffusion mechanism by partially decoupling the cations from the anions and solvent molecules.The G4 system,in contrast,is dominated by the formation of long-lived,stable[Li(G4)]+solvation cages that results in a sluggish Li+transport.The difference between the two transport mechanisms is discussed via comparison of the bulk ionic conductivity,viscosity,ion self-diffusion coefficients,and the Onsager transport coefficients.

关 键 词：anion-blocking conditions ion correlations low-frequency impedance spectroscopy transference number 

分 类 号：TM912[电气工程—电力电子与电力传动]