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Euv

Extreme ultraviolet (EUV) refers to the portion of the electromagnetic spectrum with wavelengths roughly from 10 to 121 nanometers. EUV lies between the vacuum ultraviolet and soft X-ray regions and is strongly absorbed by air, so experiments and observations are conducted in vacuum or in controlled inert gas environments.

EUV photons have high energy and can easily photoionize most materials, causing rapid damage to optical surfaces.

Industrially, the dominant application is extreme ultraviolet lithography (EUVL) for semiconductor manufacturing. The 13.5 nm band

Key challenges include achieving sufficient photon flux, preserving mirror reflectivity in a harsh vacuum, preventing contamination

Beyond lithography, EUV studies contribute to understanding hot astrophysical plasmas, enabling observations of the Sun's corona

Conventional
glass
and
many
coatings
are
opaque
at
these
wavelengths,
so
EUV
systems
rely
on
reflective
optics
rather
than
lenses.
Typical
EUV
mirrors
use
multilayer
coatings
(for
example
alternating
molybdenum
and
silicon
layers)
and
are
configured
as
grazing-incidence
or
near-normal
incidence
components
tuned
for
specific
bands
around
13.5
nm
or
other
wavelengths.
is
generated
by
laser-produced
plasma
sources
(often
tin
microdroplets)
and
requires
a
complex
vacuum
environment
and
high-precision
reflective
optics.
ASML
currently
leads
the
market
for
commercial
EUV
lithography
systems.
In
addition,
EUV
imaging
and
spectroscopy
are
used
in
solar
physics
and
high-temperature
plasma
research,
employing
space-based
telescopes
and
instruments.
and
surface
degradation,
and
producing
defect-free
masks.
The
technology
demands
extensive
vacuum
systems,
advanced
metrology,
and
substantial
operating
costs.
Safety
considerations
are
also
important
due
to
high-energy
photons
and
ionizing
radiation.
and
other
energetic
sources.