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Singleelectron

Single electron refers to the behavior or manipulation of one electron as a discrete charge carrier in nanoscale electronic systems and quantum experiments. In mesoscopic physics, single-electron effects arise when the charging energy of a small island, EC = e^2/2C, exceeds thermal energy kT, leading to Coulomb blockade and quantized transfer of charge. Devices that exhibit single-electron phenomena include the single-electron transistor (SET), the single-electron box, and quantum dot structures. In an SET, a tiny conducting island is connected to source and drain through tunnel junctions and is controlled by a gate; electrons tunnel one by one, producing measurable, discrete charge states and, under suitable drive, a current that reflects single-electron transport.

Applications of single-electron systems span metrology, electrometry, and quantum information. Single-electron devices can serve as ultra-sensitive

Challenges remain, including preserving coherence and minimizing environmental charge noise, maintaining low temperatures, and achieving reproducible

charge
detectors
and
are
explored
as
candidates
for
redefining
the
ampere
through
precise
control
of
the
elementary
charge.
In
quantum
information
research,
the
spin
or
charge
state
of
a
single
electron
in
a
quantum
dot
or
impurity
can
form
a
qubit,
with
phenomena
such
as
Pauli
spin
blockade
enabling
readout
and
manipulation.
Techniques
like
radio-frequency
SETs
(rf-SETs)
enable
rapid,
high-sensitivity
charge
detection,
and
electron
pumps
or
turnstiles
aim
to
deliver
currents
I
=
e
f
by
transferring
one
electron
per
cycle
at
frequency
f.
fabrication
of
nanostructures.
Research
continues
to
advance
single-electron
control
for
fundamental
studies
and
prospective
technological
applications.