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multiphonon

Multiphonon refers to processes in solids in which more than one phonon participates in a single interaction event, such as the creation or annihilation of two or more lattice vibrational quanta. Phonons are quantized vibrations of the crystal lattice carrying energy and crystal momentum. Multiphonon phenomena arise from anharmonic terms in the lattice potential and from higher-order couplings between electronic states and lattice vibrations.

In spectroscopic contexts, multiphonon effects appear as two-phonon or higher-order processes that produce overtones and combination

Theoretical treatment commonly uses perturbation theory applied to anharmonic lattice Hamiltonians, with selection rules determined by

Applications and relevance include material characterization, probing phonon dispersion, and studying thermal properties. In specific materials,

bands
in
Raman
or
infrared
spectra,
as
well
as
in
neutron
scattering.
Two-phonon
scattering
is
often
observable
when
single-phonon
processes
are
weak
or
symmetry-forbidden.
The
observed
frequencies
in
spectra
tend
to
be
sums
or
combinations
of
fundamental
phonon
frequencies,
and
intensities
depend
on
temperature
due
to
phonon
populations.
crystal
symmetry.
Multiphonon
processes
are
typically
weaker
than
single-phonon
processes
but
can
become
significant
at
elevated
temperatures
or
in
materials
with
strong
anharmonicity
or
resonant
electronic
structure.
multiphonon
features
are
used
to
infer
coupling
strengths
and
to
identify
crystal
structures
or
disorder.
A
well-known
example
is
the
appearance
of
two-phonon
Raman
bands
in
carbon-based
materials
such
as
graphene
and
graphite,
where
double-resonant
processes
give
characteristic
features.