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Electronbeam

An electron beam is a stream of electrons accelerated through a vacuum by an electric field, produced by an electron source such as a cathode. In typical devices, electrons are emitted from the cathode and accelerated to high energy by anode voltages or a sequence of electrodes. The beam travels in vacuum to minimize scattering and energy loss.

Emission mechanisms include thermionic emission (heated filament), field emission (sharp tip with strong electric field), and

When interacting with matter, electrons undergo elastic and inelastic scattering, producing signals such as backscattered electrons,

Major applications include electron microscopes (transmission TEM, scanning SEM, and scanning TEM) for high-resolution imaging and

Safety and handling: operation requires high voltage, high vacuum, and shielding to protect against ionizing radiation;

History: the electron was discovered by J. J. Thomson in 1897, leading to vacuum tubes, electron optics,

photoemission
(illumination
by
photons).
Beam
energy
ranges
from
tens
of
electronvolts
in
low-energy
instruments
to
hundreds
of
megaelectronvolts
in
particle
accelerators.
Beam
current
and
emittance
determine
brightness
and
focus;
magnetic
or
electrostatic
lenses
shape
and
focus
the
beam,
with
aberrations
setting
practical
limits
on
resolution.
secondary
electrons,
X-rays,
or
transmitted
electrons.
These
interactions
enable
imaging
and
spectroscopy
in
electron
microscopy
and
analysis,
as
well
as
material
processing
such
as
welding
or
surface
modification.
spectroscopy;
electron-beam
lithography
for
nanoscale
patterning;
electron-beam
welding
and
machining
in
manufacturing;
and
medical
radiotherapy,
where
therapeutic
electron
beams
penetrate
tissue.
In
research,
high-energy
electron
beams
are
used
in
accelerators
and
free-electron
lasers.
hazards
include
electrical
shock
and
exposure
to
X-rays
at
higher
energies.
and
eventually
electron
microscopy
in
the
1930s
and
beyond.