Correlating Ionic Conductivity to Structure and Dynamics of Li-Ion Battery Electrolyte Systems: Raman Spectroscopy, Dielectric Relaxation Measurements, and Streak Camera Solvation Data Analysis.

IF 2.8 2区化学 Q3 CHEMISTRY, PHYSICAL The Journal of Physical Chemistry B Pub Date : 2024-11-22 DOI:10.1021/acs.jpcb.4c05521

Amrita Mondal, Kajal Kumbhakar, Ranjit Biswas

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Abstract

A correlation between ionic conductivity and electrolyte solution structure and dynamics was explored by performing electrolyte concentration- and temperature-dependent measurements of conductivity, viscosity, and dielectric relaxation (DR) in solutions of lithium bis(trifluoromethane)sulfonimide (LiTFSI) in triethylene glycol dimethyl ether (also known as triglyme, G3). In addition, an electrolyte concentration-dependent Raman spectroscopic study and ultrafast dynamic fluorescence Stokes shift measurements of solvation of a dissolved solute by employing a streak camera detection technique were carried out. Measured conductivities (σ) and the average DR times (⟨τ_DR⟩) were found to be partially decoupled from the solution viscosities (η) and obeyed the relation, σ or ⟨τ_DR⟩^-1 ∝(η/T)^-p, with p = 0.6-0.75 for σ and p = 0.2-0.45 for ⟨τ_DR⟩^-1. Raman data indicated the formation of ion pairs and ionic aggregates in these solutions, while the measured glass transition temperature increased with LiTFSI concentration. Conductivities (σ) showed a nonlinear concentration dependence but increased linearly with the solution static dielectric constants (ε_s). The latter may be explained by considering the temperature effects on complex electrolyte species and the subsequent solution dielectric behavior. Interestingly, an inverse power-law dependence of σ on the measured DR or solvation time scales, σ ∝ (τ_x)^-m, with m = 1.2-1.9, was observed. This dependence may be explained by considering that the same environmental friction regulates both the ion diffusion and the medium polarization relaxation. The control of a slow process (ion translation) by relatively faster medium dynamics (dipolar rotation), although quite fascinating for the present system, warrants further experimental scrutiny for other electrolyte systems relevant to battery applications.

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将离子电导率与锂离子电池电解质系统的结构和动力学相关联：拉曼光谱、介电松弛测量和条纹照相机溶解数据分析。

通过对双三氟甲烷磺酰亚胺锂（LiTFSI）在三乙二醇二甲醚（又称三甘醇，G3）中溶液的电导率、粘度和介电弛豫（DR）进行电解质浓度和温度依赖性测量，探索了离子电导率与电解质溶液结构和动力学之间的相关性。此外，还进行了电解质浓度依赖性拉曼光谱研究，并采用条纹照相机检测技术对溶解溶质的溶解情况进行了超快动态荧光斯托克斯位移测量。研究发现，测量到的电导率（σ）和平均 DR 时间（ɸτ⟩）与溶液粘度（η）部分脱钩，并服从以下关系：σ 或 ⟨τDR⟩-1 ∝(η/T)-p，p = 0.6-0.75，⟨τDR⟩-1 的 p = 0.2-0.45。拉曼数据表明，在这些溶液中形成了离子对和离子聚集体，同时测得的玻璃化转变温度随 LiTFSI 浓度的增加而升高。电导率（σ）与浓度呈非线性关系，但与溶液静态介电常数（εs）呈线性关系。后者可以通过考虑温度对复杂电解质种类的影响以及随后的溶液介电行为来解释。有趣的是，σ 与所测量的 DR 或溶解时间尺度（σ ∝ (τx)-m, m = 1.2-1.9）之间存在反幂律关系。考虑到同一环境摩擦同时调节离子扩散和介质极化松弛，可以解释这种依赖性。相对较快的介质动力学（双极旋转）对缓慢过程（离子平移）的控制，虽然对本系统而言相当吸引人，但值得对与电池应用相关的其他电解质系统进行进一步的实验研究。

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来源期刊

The Journal of Physical Chemistry B 化学-物理化学

CiteScore

5.80

自引率

9.10%

发文量

965

审稿时长

1.6 months

期刊介绍： An essential criterion for acceptance of research articles in the journal is that they provide new physical insight. Please refer to the New Physical Insights virtual issue on what constitutes new physical insight. Manuscripts that are essentially reporting data or applications of data are, in general, not suitable for publication in JPC B.