What does a semicircle in a Nyquist plot represent?

A semicircle arises from the parallel combination of charge-transfer resistance and double-layer capacitance; its diameter gives the charge-transfer resistance, a direct measure of how fast the electrode reaction proceeds.

Why must the applied signal amplitude be small?

The analysis assumes a linear current–potential response; only a small perturbation (typically a few millivolts) keeps the system in its linear regime so that a single well-defined impedance can be assigned at each frequency.

Electrochemical Impedance Spectroscopy

Electrochemical impedance spectroscopy applies a small alternating potential across a range of frequencies and analyzes the current response to separate the resistive and capacitive processes occurring at an electrode.

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Definition

An electroanalytical method that measures the complex impedance of an electrochemical system as a function of the frequency of a small alternating signal, to characterize interfacial and transport processes.

Scope

This topic covers the impedance technique: small-amplitude sinusoidal perturbation, the frequency-domain response displayed in Nyquist and Bode plots, the interpretation of spectra through equivalent electrical circuits incorporating solution resistance, double-layer capacitance, charge-transfer resistance, and Warburg diffusion, and the validity conditions for linear analysis. It resolves interfacial phenomena by their characteristic time scales.

Core questions

How does a small alternating signal probe processes occurring at different time scales at an electrode?
How are Nyquist and Bode plots interpreted to extract kinetic and transport parameters?
What do the elements of an equivalent circuit represent physically?
Why must the perturbation be small for the impedance analysis to be valid?

Key theories

Equivalent circuit modeling: The interface is represented by combinations of resistors and capacitors—solution resistance, double-layer capacitance, charge-transfer resistance, and Warburg diffusion impedance—whose values are fitted to the measured spectrum to quantify the underlying processes.
Warburg diffusion impedance: At low frequencies, slow diffusion of reactants produces a characteristic 45-degree line in the Nyquist plot, providing a frequency-resolved signature of mass-transport control distinct from charge transfer.

Clinical relevance

Impedance spectroscopy diagnoses battery and fuel-cell degradation, characterizes corrosion and protective coatings, evaluates electrode materials and biosensor interfaces, and underpins label-free impedimetric biosensing of binding events at surfaces.

History

Warburg analyzed diffusion impedance around 1899 and Randles proposed the canonical equivalent circuit for an electrode interface in 1947; modern frequency-response analyzers and computational fitting from the late 20th century made impedance spectroscopy a routine diagnostic across electrochemistry.

Key figures

Emil Warburg
John E. B. Randles
Mark Orazem

Seminal works

bard2001
orazem2008
lasia2014

Frequently asked questions

What does a semicircle in a Nyquist plot represent?: A semicircle arises from the parallel combination of charge-transfer resistance and double-layer capacitance; its diameter gives the charge-transfer resistance, a direct measure of how fast the electrode reaction proceeds.
Why must the applied signal amplitude be small?: The analysis assumes a linear current–potential response; only a small perturbation (typically a few millivolts) keeps the system in its linear regime so that a single well-defined impedance can be assigned at each frequency.