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photoluminescence

Photoluminescence is luminescence produced by the absorption of photons by a material followed by emission of light. The absorbed energy promotes electrons to higher electronic states, after which the excited system returns to lower energy levels by radiative and non-radiative processes. If the emitted photon energy is lower than the excitation energy, the process exhibits a Stokes shift.

Fluorescence is a fast form of photoluminescence in which emission occurs from the initially excited singlet

The efficiency of photoluminescence is described by quantum yield, the ratio of emitted to absorbed photons,

Applications span lighting and displays, where photoluminescent compounds convert absorbed energy to visible light; bioimaging and

Measurement typically involves excitation with a light source such as a lamp or laser and detection of

state
and
typically
lasts
from
picoseconds
to
nanoseconds.
Phosphorescence
involves
emission
from
a
triplet
state
and
is
slower
due
to
spin-forbidden
transitions,
ranging
from
microseconds
to
seconds
or
longer.
Some
materials
show
delayed
fluorescence,
such
as
thermally
activated
delayed
fluorescence.
and
is
influenced
by
nonradiative
losses
and
environmental
factors.
Emission
spectra
reveal
the
energy
structure
of
the
material
and
can
be
tuned
by
size,
composition,
and
crystal
field
effects.
Common
photoluminescent
materials
include
organic
dyes,
inorganic
phosphors,
quantum
dots,
and
perovskites.
sensing,
where
fluorescence
signals
report
on
chemical
or
biological
processes;
and
materials
characterization,
where
luminescence
lifetimes
and
spectra
provide
information
about
electronic
structure
and
interactions.
emitted
photons
as
a
function
of
wavelength
and
time.
Factors
such
as
concentration
quenching,
temperature,
and
solvent
can
affect
intensity
and
spectra.