Determination of diffusion coefficient of lithium in substituted LiMn1.95Cr0.05O4 spinel using impedance technique

“…(2) The impedance spectrum of commercial lithium-ion batteries is notoriously difficult to interpret. Churikov et al [3] studied the electrical diffusion properties of chromium-substituted lithium-manganese spinel Li x-Mn 1.95 Cr 0.05 O 4 used as cathode material for lithium-ion batteries and discussed the selection of equivalent circuits and the correct interpretation of equivalent circuit elements. (3) Hirose et al [4] emphasised the importance of choosing a suitable equivalent circuit to model the impedance response.…”

Comparative study of two equivalent circuit models for electrochemical impedance spectroscopy analysis of epoxy zinc-rich coatings

“…(2) The impedance spectrum of commercial lithium-ion batteries is notoriously difficult to interpret. Churikov et al [3] studied the electrical diffusion properties of chromium-substituted lithium-manganese spinel Li x-Mn 1.95 Cr 0.05 O 4 used as cathode material for lithium-ion batteries and discussed the selection of equivalent circuits and the correct interpretation of equivalent circuit elements. (3) Hirose et al [4] emphasised the importance of choosing a suitable equivalent circuit to model the impedance response.…”

Comparative study of two equivalent circuit models for electrochemical impedance spectroscopy analysis of epoxy zinc-rich coatings

“…R 3 is the charge-transfer resistance during the electrochemical reaction process. W 1 represents the Warburg impedance concerning the diffusion of Li + into the bulk electrode and C 1 and C 2 represent the constant phase elements that are used to cancel the measurement error and hysteresis effect [30,34].…”

High-performance of sodium carboxylate-derived materials for electrochemical energy storage

Diffusion aspects of lithium intercalation as applied to the development of electrode materials for lithium-ion batteries