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fluorescerande

Fluorescerande describes a property where a substance emits light after being excited by another energy source, usually by absorbing higher-energy photons and releasing photons with longer wavelengths. This phenomenon is a form of luminescence called fluorescence. The term traces its origin to observations of glowing minerals such as fluorite under ultraviolet light.

In a fluorescent material, photons promote electrons from a ground state to a higher-energy singlet state. The

Fluorescerande materials encompass a wide range of substances. Organic dyes such as fluorescein and rhodamine, fluorescent

Applications span science, medicine, industry and safety. In biology and medicine, fluorescence enables microscopy, flow cytometry,

excited
electrons
quickly
return
to
the
ground
state,
emitting
light
in
the
visible
range
or
other
parts
of
the
spectrum.
The
emission
stops
when
the
excitation
source
is
removed,
occurring
on
a
very
fast
timescale
(nanoseconds).
The
difference
between
the
excitation
and
emission
wavelengths
is
known
as
the
Stokes
shift.
The
efficiency
of
fluorescence
is
described
by
the
quantum
yield,
which
varies
between
substances
and
depends
on
factors
like
environment
and
concentration.
proteins
like
GFP
and
its
derivatives,
and
inorganic
options
like
quantum
dots
or
rare-earth–doped
crystals
are
common
examples.
Fluorescence
is
also
exploited
in
coatings
and
pigments
that
glow
under
ultraviolet
light,
as
well
as
in
fluorescent
phosphors
used
in
lighting
and
display
technologies.
DNA
probes
and
diagnostic
assays.
In
industry,
fluorescent
materials
are
used
for
security
features,
anti-counterfeiting,
sensors
and
imaging
technologies.
Limitations
include
photobleaching
(loss
of
signal
with
light
exposure)
and
potential
toxicity
or
environmental
concerns
for
certain
dyes.