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chronoamperometry

Chronoamperometry is an electrochemical technique in which a potential is applied to a working electrode at time zero and the resulting current is recorded as a function of time. The method is used to study redox processes by observing transient currents after a potential step, providing information about diffusion, kinetics, and concentrations.

Typically, chronoamperometry uses a three-electrode cell with a working electrode, a reference electrode, and a counter

In diffusion-controlled cases, the current decay follows a Cottrell-type behavior, described by i(t) = n F A

Instrumentation and setup for chronoamperometry typically involve a stable potentiostat, a glassy carbon, platinum, or gold

Applications include determination of diffusion coefficients, kinetic parameters of electron transfer, sensor development, and characterization of

electrode.
The
potential
is
stepped
from
a
baseline
value
to
a
value
that
drives
the
desired
oxidation
or
reduction.
The
recorded
current
initially
contains
a
capacitive
(double-layer)
component,
which
decays
rapidly,
after
which
the
faradaic
current
due
to
species
diffusion
to
the
electrode
dominates.
The
resulting
chronoamperogram
can
be
analyzed
to
extract
transport
and
kinetic
parameters.
C
/
sqrt(pi
D
t),
where
n
is
the
number
of
electrons
transferred,
F
is
Faraday’s
constant,
A
is
electrode
area,
C
is
bulk
concentration,
D
is
the
diffusion
coefficient,
and
t
is
time.
In
systems
with
slower
kinetics
or
reversible
couples,
electrode
kinetics
modify
the
transient
shape
and
the
surface
concentration
dynamics,
enabling
estimation
of
rate
constants
and
transfer
coefficients
through
fitting
to
appropriate
models.
working
electrode,
a
reference
electrode
such
as
Ag/AgCl,
a
counter
electrode,
and
a
supporting
electrolyte.
Microelectrodes
can
reduce
i
and
enhance
steady-state
control.
Data
analysis
may
use
analytical
expressions
for
simple
regimes
or
numerical
simulations
for
complex
kinetics.
battery
and
corrosion
processes.