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nanophotonica

Nanophotonica, or nanophotonics, is the study of light-matter interactions at nanometer scales, where the size of structures and their spacing approach the wavelength of light. In this regime, nanostructuring can confine, guide, and manipulate photons beyond the diffraction limit, enabling control of optical fields at subwavelength scales.

The field encompasses several subareas, including plasmonics, dielectric nanophotonics, metamaterials and metasurfaces, photonic crystals, and nanoscale

Quantum nanophotonics studies the interaction of quantum emitters—such as quantum dots or color centers—with nanostructured environments

Applications include chemical and biological sensing, spectroscopy and imaging, on-chip optical communication, nonlinear and quantum information

Key challenges include material losses in metals, fabrication precision and variability, thermal management, device scalability, and

waveguides
and
resonators.
Plasmonics
uses
collective
electron
oscillations
in
metals
to
concentrate
light
into
nanoscale
volumes,
often
with
strong
field
enhancement
but
with
inherent
losses.
Dielectric
nanophotonics
relies
on
high-index
materials
to
confine
light
with
lower
losses.
Metasurfaces
and
metamaterials
engineer
phase,
amplitude,
and
polarization
with
subwavelength
elements
to
achieve
unusual
optical
responses.
to
realize
efficient
single-photon
sources,
entangled
photons,
and
enhanced
light-matter
coupling.
Fabrication
and
integration
employ
lithography,
self-assembly,
and
chemical
synthesis
of
nanostructures,
along
with
integration
with
silicon
photonics
for
on-chip
functionality.
processing,
and
improvements
in
photovoltaics
and
light-emitting
devices.
Characterization
uses
near-field
techniques
(NSOM/s-SNOM),
electron
energy
loss
spectroscopy,
and
cathodoluminescence
to
map
local
optical
responses
and
the
local
density
of
states.
integration
with
existing
technologies.
Ongoing
research
aims
to
enable
practical
nanophotonic
systems
with
enhanced
performance
and
new
functionalities.