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nanoelectromechanical

Nanoelectromechanical systems, or NEMS, are devices that integrate electrical and mechanical functionality on nanoscale structures. They extend the concepts of MEMS into the nanometer range, using components such as cantilevers, beams, membranes, and resonators with dimensions from tens to hundreds of nanometers. NEMS devices exploit electromechanical coupling to sense or actuate motion, with readout typically achieved through electrostatic, piezoelectric, magnetic, or optical methods. They can operate as high-frequency resonators with low mass and high sensitivity to external forces or masses.

NEMS developed from MEMS research, with early demonstrations in the 2000s using carbon nanotubes and silicon

Applications of NEMS include ultrasensitive mass, force, and chemical or biological sensing, as well as RF switches

Overall, NEMS hold potential for compact, high-performance sensing and signal processing, with ongoing work aimed at

nanowires.
Platforms
include
carbon
nanotube
resonators,
graphene
membranes,
silicon
nanobeams,
and
other
low-dimensional
materials.
Fabrication
combines
top-down
lithography
and
etching
with
release
processes
to
create
suspended
nanoscale
structures,
while
bottom-up
synthesis
is
also
used
for
certain
materials.
Readout
schemes
often
integrate
transistors
or
rely
on
external
transducers.
and
filters,
timing
references,
and
nanoactuators.
In
fundamental
research,
NEMS
enable
experiments
at
the
intersection
of
classical
and
quantum
mechanics,
particularly
when
cooled
to
low
temperatures.
Challenges
remain
in
achieving
high
mechanical
quality
factors,
reducing
dissipation,
integrating
with
electronics,
packaging,
and
scalable
manufacturing.
improving
reliability
and
CMOS
compatibility.