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Transmission electron microscopy (TEM) is a microscopy technique in which a beam of electrons is transmitted through an ultra-thin specimen to form an image. Because electrons have wavelengths far shorter than visible light, TEM can achieve atomic-scale resolution, enabling visualization of crystal lattices, defects, and nanostructures. Typical TEM operation uses accelerating voltages around 60–300 kilovolts, and samples are prepared to be electron transparent, often requiring thinning to tens of nanometers.

In a TEM, an electron source generates a beam that is shaped by condenser lenses, then directed

Sample preparation is crucial and varies by material. Biological specimens may be embedded and cryo-preserved or

Applications of TEM span materials science, chemistry, physics, and biology. It enables defect analysis, lattice imaging,

onto
the
specimen.
Transmitted
electrons
are
collected
by
an
objective
lens
and
projected
onto
a
detector
or
imaging
screen
to
produce
a
magnified
image.
Contrast
results
from
differences
in
how
electrons
scatter
within
the
sample,
with
thicker
or
denser
regions
producing
more
scattering.
TEM
also
supports
diffraction
modes
to
study
crystal
structure
and
orientation,
and
can
be
combined
with
spectroscopic
techniques
for
composition
analysis.
stained
to
enhance
contrast,
while
materials
and
nanomaterials
are
thinned
by
microtomy,
ion
milling,
or
focused
ion
beam
techniques.
Imaging
modalities
include
bright-field
and
dark-field
TEM,
as
well
as
high-resolution
TEM
(HRTEM).
Scanning
TEM
(STEM)
is
a
related
mode
that
scans
a
focused
electron
probe
across
the
sample,
often
paired
with
detectors
for
energy-dispersive
X-ray
spectroscopy
(EDS)
or
electron
energy
loss
spectroscopy
(EELS)
for
elemental
analysis.
nanostructure
characterization,
and
atomic-scale
crystallography.
Electron
diffraction,
tomography,
and
spectroscopy
extend
TEM’s
capabilities
to
three-dimensional
reconstruction
and
composition
mapping.
The
technique
traces
its
origins
to
early
work
by
Ernst
Ruska
and
Max
Knoll
in
the
1930s
and
remains
a
cornerstone
of
high-resolution
characterization.