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micromotors

Micromotors are miniature electric motors designed to produce rotational or linear motion at small scales, typically ranging from tens of micrometers to a few millimeters in size. They are used in settings where conventional motors are impractical due to space, weight, or energy constraints. Micromotors can be categorized by actuation method, including electric motors powered by micro-scale circuits (such as brushless DC, brushed DC, and stepper designs), ultrasonic motors driven by high-frequency vibrations, piezoelectric motors that convert electric field-induced strain into motion, and magnetic motors that use external magnetic fields to drive a rotor. Linear micromotors are also available.

Construction and operation of micromotors often rely on microfabrication techniques from MEMS (microelectromechanical systems), enabling integration

Applications of micromotors span several fields. In MEMS and microfluidics, they actuate valves, pumps, and mixers

with
sensors
and
other
circuitry.
Common
materials
include
silicon,
ceramics,
and
polymers.
Bearings
and
lubrication
are
critical
at
micro
scales,
with
some
designs
minimizing
wear
through
magnetic
bearings,
air
bearings,
or
purely
non-contact
operation.
Power
sources
range
from
miniature
batteries
and
wireless
power
transfer
to
externally
applied
magnetic
fields.
Control
systems
use
specialized
electronics
and
feedback
from
integrated
sensors
to
regulate
speed
and
torque.
within
tiny
fluidic
networks.
In
micro-robotics,
they
provide
actuation
for
joints,
wheels,
or
grippers
in
small
robots.
Medical
devices
use
micromotors
for
targeted
drug
delivery
or
minimally
invasive
tools,
and
in
optics
they
drive
micro-positioners
or
switches.
Challenges
include
fabrication
complexity,
limited
torque
and
efficiency,
wear
and
heat
management,
and
integration
with
power
and
control
systems.
Ongoing
research
seeks
to
improve
reliability,
biocompatibility,
and
performance
in
real-world
environments.