Impedance Spectroscopy for Electroceramics and Electrochemical System

TL;DR

This tutorial review explains the principles and applications of impedance spectroscopy in electroceramics and electrochemical systems, highlighting how it helps analyze various material and system properties across different fields.

Contribution

It provides a comprehensive overview of impedance spectroscopy's theoretical background, implementation, and interpretation in electroceramics and electrochemical research, aiding both senior and junior researchers.

Findings

Disentangles contributions to impedance spectra in electroceramics and electrochemistry.

Demonstrates impedance spectroscopy's effectiveness in understanding charge transport and dielectric properties.

Provides practical insights for analyzing energy storage, corrosion, and sensing systems.

Abstract

This tutorial review focuses on the basic theoretical backgrounds, their working principles, and implementation of impedance spectroscopy in both electroceramics and electrochemical research and technological applications. Various contributions to the impedance, admittance, dielectric, and conductivity characteristics of electroceramic materials can be disentangled and independently characterized with the help of impedance spectroscopy as a function of frequency and temperature. In polycrystalline materials, the impedance, charge transport/ conduction mechanism, and the macroscopic dielectric properties i.e., dielectric constant and loss are typically composed of many contributions, including the bulk or grain resistance/capacitance, grain boundary, and sample-electrode interface effect. Similarly, electrochemical impedance spectroscopy (EIS) endeavors to the charging kinetics, diffusion, and mechanical impact of various electrochemical systems widely used in energy storage (i.e., supercapacitor, battery), corrosion resistance, chemical and bio-sensing, diagnostics, etc. in electrolytes as a function of frequency. The understanding of various contributions in the EIS spectra i.e., kinetic control, mass control, and diffusion control is essential for their practical implications. It is demonstrated that electrochemical and electroceramics impedance spectroscopy is an effective method to explain and simulate such behavior. Deconvolute these contributions to obtain a detailed understanding of the functionality of polycrystalline electroceramic materials. This short review aims to endow the expertise of senior researchers in many fields where both EIS (electrochemical and ceramics) are involved, as well as to provide the necessary background information for junior researchers working in these fields.