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plasmonic

Plasmonics is the study and application of plasmons—collective oscillations of free electrons in conducting solids excited by light. In nanostructures these excitations can couple to photons as surface plasmon polaritons (SPPs), which travel along metal–dielectric interfaces, or as localized surface plasmon resonances (LSPRs) in metallic nanoparticles, yielding strong confinement of the electromagnetic field near the surface. Descriptions typically combine the Drude model with Maxwell’s equations. Plasmonic resonances depend on material properties, geometry, size, and the surrounding medium; smaller structures push resonances into the visible or near-infrared and enhance local fields.

Gold and silver are common plasmonic materials in the visible range; aluminum is used for ultraviolet applications.

Applications span plasmonic sensing, where refractive-index changes shift LSPR peaks; surface-enhanced Raman scattering and related spectroscopy;

Other
plasmonic
materials
include
titanium
nitride,
copper,
and
doped
oxides,
while
graphene
supports
infrared
plasmons.
Losses
due
to
electron
scattering
limit
propagation
and
quality
factors,
affecting
long-range
transport.
Fabrication
uses
lithography
or
chemical
synthesis
to
create
shapes
such
as
spheres,
rods,
and
prisms
that
tailor
LSPR
frequencies
for
sensing,
spectroscopy,
and
photonic
devices.
optical
imaging
and
photothermal
therapy;
subwavelength
waveguides
and
metasurfaces
for
nanophotonic
circuits;
and
enhancements
in
photovoltaics
and
photocatalysis.
The
field
seeks
high
field
confinement
with
manageable
losses
and
ongoing
development
of
new
materials
and
structures
to
extend
operation
ranges
and
enable
integration
with
conventional
optics.