Nano Letters,
Journal Year:
2024,
Volume and Issue:
24(2), P. 557 - 565
Published: Jan. 5, 2024
The
manipulation
of
molecular
excited
state
processes
through
strong
coupling
has
attracted
significant
interest
for
its
potential
to
provide
precise
control
photochemical
phenomena.
However,
the
key
limiting
factor
achieving
this
been
"dark-state
problem",
in
which
photoexcitation
populates
long-lived
reservoir
states
with
energies
and
dynamics
similar
those
bare
excitons.
Here,
we
use
a
sensitive
ultrafast
transient
reflection
method
momentum
spectral
resolution
achieve
selective
excitation
organic
exciton-polaritons
open
photonic
cavities.
We
show
that
energy
dispersions
these
systems
allow
us
avoid
parasitic
effect
states.
Under
phase-matching
conditions,
observe
direct
population
decay
polaritons
on
time
scales
less
than
100
fs
find
scattering
occur
even
faster
scales.
establish
it
is
possible
overcome
"dark
problem"
careful
design
strongly
coupled
systems.
Chemical Reviews,
Journal Year:
2023,
Volume and Issue:
123(16), P. 9786 - 9879
Published: Aug. 8, 2023
When
molecules
are
coupled
to
an
optical
cavity,
new
light-matter
hybrid
states,
so-called
polaritons,
formed
due
quantum
interactions.
With
the
experimental
demonstrations
of
modifying
chemical
reactivities
by
forming
polaritons
under
strong
interactions,
theorists
have
been
encouraged
develop
methods
simulate
these
systems
and
discover
strategies
tune
control
reactions.
This
review
summarizes
some
exciting
theoretical
advances
in
polariton
chemistry,
ranging
from
fundamental
framework
computational
techniques
applications
spanning
photochemistry
vibrational
coupling.
Even
though
theory
interactions
goes
back
midtwentieth
century,
gaps
knowledge
molecular
electrodynamics
(QED)
only
recently
filled.
We
recent
made
resolving
gauge
ambiguities,
correct
form
different
QED
Hamiltonians
gauges,
their
connections
various
optics
models.
Then,
we
developed
ab
initio
approaches
which
can
accurately
describe
states
a
realistic
molecule-cavity
system.
then
discuss
using
method
advancements.
advancements
where
cavity
is
resonant
electronic
transitions
nonadiabatic
excited
state
dynamics
enable
photochemical
reactivities.
resonance
tuned
vibrations
instead,
ground-state
reaction
modifications
demonstrated
experimentally,
its
mechanistic
principle
remains
unclear.
present
progress
this
mystery.
Finally,
understanding
collective
coupling
regime
between
light
matter,
many
collectively
couple
single
mode
or
modes.
also
lay
out
current
challenges
explain
observed
results.
hope
that
will
serve
as
useful
document
for
anyone
who
wants
become
familiar
with
context
chemistry
thus
significantly
benefit
entire
community.
Chemical Reviews,
Journal Year:
2023,
Volume and Issue:
123(18), P. 10877 - 10919
Published: Sept. 8, 2023
The
interaction
between
molecular
electronic
transitions
and
electromagnetic
fields
can
be
enlarged
to
the
point
where
distinct
hybrid
light-matter
states,
polaritons,
emerge.
photonic
contribution
these
states
results
in
increased
complexity
as
well
an
opening
modify
photophysics
photochemistry
beyond
what
normally
seen
organic
molecules.
It
is
today
evident
that
polaritons
offer
opportunities
for
photophysics,
which
has
caused
ever-rising
interest
field.
Focusing
on
experimental
landmarks,
this
review
takes
its
reader
from
advent
of
field
polaritonic
chemistry,
over
split
into
polariton
chemistry
photochemistry,
present
day
status
within
photophysics.
To
introduce
field,
starts
with
a
general
description
interactions,
how
enhance
these,
characterizes
coupling
strength.
Then
strongly
coupled
systems
using
Fabry-Perot
plasmonic
cavities
are
described.
This
followed
by
room-temperature
Bose-Einstein
condensation/polariton
lasing
systems.
ends
discussion
benefits,
limitations,
future
developments
strong
exciton-photon
Nature Communications,
Journal Year:
2023,
Volume and Issue:
14(1)
Published: June 30, 2023
Abstract
Semiconductor
excitations
can
hybridize
with
cavity
photons
to
form
exciton-polaritons
(EPs)
remarkable
properties,
including
light-like
energy
flow
combined
matter-like
interactions.
To
fully
harness
these
EPs
must
retain
ballistic,
coherent
transport
despite
matter-mediated
interactions
lattice
phonons.
Here
we
develop
a
nonlinear
momentum-resolved
optical
approach
that
directly
images
in
real
space
on
femtosecond
scales
range
of
polaritonic
architectures.
We
focus
our
analysis
EP
propagation
layered
halide
perovskite
microcavities.
reveal
EP–phonon
lead
large
renormalization
velocities
at
high
excitonic
fractions
room
temperature.
Despite
strong
interactions,
ballistic
is
maintained
for
up
half-exciton
EPs,
agreement
quantum
simulations
dynamic
disorder
shielding
through
light-matter
hybridization.
Above
50%
character,
rapid
decoherence
leads
diffusive
transport.
Our
work
provides
general
framework
precisely
balance
coherence,
velocity,
and
The Journal of Chemical Physics,
Journal Year:
2025,
Volume and Issue:
162(13)
Published: April 1, 2025
Strong
light–matter
interactions
have
generated
considerable
interest
as
a
means
to
manipulate
material
properties.
Here,
we
explore
this
possibility
with
the
molecular
superconductor
Rb3C60
under
vibrational
strong
coupling
(VSC)
surface
plasmon
polaritons.
By
placing
superconductor-surface
system
in
SQUID
magnetometer,
find
that
superconducting
transition
temperature
(Tc)
increases
from
30
45
K
at
normal
pressures
VSC,
displaying
well-defined
Meissner
effect.
A
simple
theoretical
framework
is
provided
understand
these
results
based
on
an
enhancement
of
electron–phonon
coupling.
This
proof-of-principle
study
opens
new
tool
box
not
only
modify
materials
but
also
mechanistic
details
different
superconductors.
Chemical Reviews,
Journal Year:
2024,
Volume and Issue:
124(5), P. 2512 - 2552
Published: Feb. 28, 2024
Molecular
polaritons
are
quasiparticles
resulting
from
the
hybridization
between
molecular
and
photonic
modes.
These
composite
entities,
bearing
characteristics
inherited
both
constituents,
exhibit
modified
energy
levels
wave
functions,
thereby
capturing
attention
of
chemists
in
past
decade.
The
potential
to
modify
chemical
reactions
has
spurred
many
investigations,
alongside
efforts
enhance
manipulate
optical
responses
for
quantum
applications.
This
Review
centers
on
experimental
advances
this
burgeoning
field.
Commencing
with
an
introduction
fundamentals,
including
theoretical
foundations
various
cavity
architectures,
we
discuss
outcomes
polariton-modified
reactions.
Furthermore,
navigate
through
ongoing
debates
uncertainties
surrounding
underpinning
mechanism
innovative
method
controlling
chemistry.
Emphasis
is
placed
gaining
a
comprehensive
understanding
dynamics
polaritons,
particular,
vibrational
polaritons─a
pivotal
facet
steering
Additionally,
unique
capability
coherent
two-dimensional
spectroscopy
dissect
polariton
dark
mode
dynamics,
offering
insights
into
critical
components
within
that
alter
We
further
expand
utility
applications
as
well
precise
manipulation
polarizations,
notably
context
chiral
phenomena.
discussion
aspires
ignite
deeper
curiosity
engagement
revealing
physics
properties,
broad
fascination
harnessing
environments
control
The Journal of Chemical Physics,
Journal Year:
2025,
Volume and Issue:
162(1)
Published: Jan. 7, 2025
We
outline
two
general
theoretical
techniques
to
simulate
polariton
quantum
dynamics
and
optical
spectra
under
the
collective
coupling
regimes
described
by
a
Holstein–Tavis–Cummings
(HTC)
model
Hamiltonian.
The
first
one
takes
advantage
of
sparsity
HTC
Hamiltonian,
which
allows
reduce
cost
acting
Hamiltonian
onto
state
vector
linear
order
number
states,
instead
quadratic
order.
second
is
applying
well-known
Chebyshev
series
expansion
approach
for
propagation
in
system;
this
us
use
much
larger
time
step
only
requires
few
recursive
operations
on
vectors.
These
approaches
are
can
be
applied
any
trajectory-based
non-adiabatic
methods.
apply
these
with
our
previously
developed
Lindblad-partially
linearized
density
matrix
absorption
system,
both
inhomogeneous
site
energy
disorders
dipolar
orientational
disorders.
Our
numerical
results
agree
well
previous
analytic
work.
Nano Letters,
Journal Year:
2025,
Volume and Issue:
unknown
Published: Jan. 21, 2025
Recent
experiments
have
shown
that
exciton
transport
can
be
significantly
enhanced
through
hybridization
with
confined
photonic
modes
in
a
cavity.
The
light-matter
generates
exciton-polariton
(EP)
bands,
whose
group
velocity
is
larger
than
the
excitons.
Dissipative
mechanisms
affect
constituent
states
of
EPs,
such
as
exciton–phonon
coupling
and
cavity
loss,
been
observed
to
reduce
velocities
experiments.
To
elucidate
impacts
these
dissipative
on
polariton
transport,
we
developed
an
efficient
quantum
dynamics
approach
allows
us
directly
simulate
under
collective
regime
beyond
long-wavelength
approximation.
Our
numerical
results
suggest
renormalization
stronger
strengths
smaller
Q-factor.
We
observe
transition
from
ballistic
diffusive
propagation
well
quality-factor-dependent
behavior
transient
mean
square
displacement,
agreeing
recent
experimental
measurements.
Physical Review Letters,
Journal Year:
2023,
Volume and Issue:
130(21)
Published: May 24, 2023
Experiments
have
demonstrated
that
the
strong
light-matter
coupling
in
polaritonic
microcavities
significantly
enhances
transport.
Motivated
by
these
experiments,
we
solved
disordered
multimode
Tavis-Cummings
model
thermodynamic
limit
and
used
this
solution
to
analyze
its
dispersion
localization
properties.
The
implies
wave-vector-resolved
spectroscopic
quantities
can
be
described
single-mode
models,
but
spatially
resolved
require
solution.
Nondiagonal
elements
of
Green's
function
decay
exponentially
with
distance,
which
defines
coherence
length.
coherent
length
is
strongly
correlated
photon
weight
exhibits
inverse
scaling
respect
Rabi
frequency
an
unusual
dependence
on
disorder.
For
energies
away
from
average
molecular
energy
E_{M}
above
confinement
E_{C},
rapidly
diverges
such
it
exceeds
resonance
wavelength
λ_{0}.
rapid
divergence
allows
us
differentiate
localized
delocalized
regimes
identify
transition
diffusive
ballistic
Nature Communications,
Journal Year:
2023,
Volume and Issue:
14(1)
Published: Oct. 19, 2023
Exciton
transport
can
be
enhanced
in
the
strong
coupling
regime
where
excitons
hybridize
with
confined
light
modes
to
form
polaritons.
Because
polaritons
have
group
velocity,
their
propagation
should
ballistic
and
long-ranged.
However,
experiments
indicate
that
organic
propagate
a
diffusive
manner
more
slowly
than
velocity.
Here,
we
resolve
this
controversy
by
means
of
molecular
dynamics
simulations
Rhodamine
molecules
Fabry-Pérot
cavity.
Our
results
suggest
polariton
is
limited
cavity
lifetime
appears
due
reversible
population
transfers
between
polaritonic
states
ballistically
at
dark
are
stationary.
Furthermore,
because
long-lived
transiently
trap
excitation,
observed
on
timescales
beyond
intrinsic
lifetime.
These
insights
not
only
help
better
understand
interpret
experimental
observations,
but
also
pave
way
towards
rational
design
molecule-cavity
systems
for
coherent
exciton
transport.
