Angewandte Chemie,
Год журнала:
2024,
Номер
unknown
Опубликована: Ноя. 8, 2024
Abstract
Given
homomorphic
fluorine
(F),
chlorine
(Cl)
and
bromine
(Br)
atoms
are
featured
with
gradually
enlarged
polarizability/atomic
radius
but
decreased
electronegativity,
the
rational
screen
of
halogen
species
locations
on
small
molecular
acceptors
(SMAs)
is
quite
essential
for
acquiring
desirable
packing
to
boost
efficiency
organic
solar
cells
(OSCs).
Herein,
three
isomeric
SMAs
(CH−F,
CH−C
CH−B)
constructed
by
delicately
rebuilding
peripheral
F,
Cl,
Br
footprints
both
central
end
units.
Such
a
re‐permutation
halogens
could
not
only
maintain
structural
symmetry
maximum,
also
acquire
extra
asymmetric
benefits
enhanced
dipole
moment
intramolecular
charge
transfer,
etc.
Moreover,
brominating
enhances
crystallinity
CH−B
without
introducing
undesirable
steric
hindrance
groups,
thus
rendering
better
balance
between
high
crystallization
domain
size
control
in
PM6:CH−B
blend.
Further
benefitting
from
large
dielectric
constant,
exciton
binding
energy,
optimized
great
electron
transfer
integral,
affords
first
class
binary
OSC
19.78
%,
moreover,
highest
18.35
%
far
when
increasing
active
layer
thickness
~300
nm.
Our
successful
screening
provides
valuable
insight
into
further
design
record‐breaking
OSCs.
Journal of the American Chemical Society,
Год журнала:
2024,
Номер
unknown
Опубликована: Дек. 2, 2024
Constructing
fibril
morphology
has
been
believed
to
be
an
effective
method
of
achieving
efficient
exciton
dissociation
and
charge
transport
in
organic
solar
cells
(OSCs).
Despite
emerging
endeavors
on
the
fibrillization
semiconductors
via
chemical
structural
design
or
physical
manipulation,
tuning
geometry,
i.e.,
width
length,
for
tailored
optoelectronic
properties
remains
studied
depth.
In
this
work,
a
series
alkoxythiophene
additives
featuring
varied
alkyl
side
chains
connected
thiophene
are
designed
modulate
growth
aggregates
cutting-edge
polymer
donors
PM6
D18.
Molecular
dynamics
simulations
morphological
characterizations
reveal
that
these
preferentially
locate
near
entangle
with
donors,
which
enhance
conjugated
backbone
stacking
form
nanofibrils
expanding
from
12.6
21.8
nm
length
increasing
98.3
232.7
nm.
This
nanofibril
structure
is
feasible
acquire
simultaneously.
By
integrating
L8-BO
as
donor
acceptor
layers
pseudo-bulk
heterojunction
(p-BHJ)
OSCs
layer-by-layer
deposition,
improvement
power
conversion
efficiency
(PCE)
18.7%
19.8%
observed,
contributed
by
enhanced
light
absorption,
transport,
reduced
recombination.
The
versatility
also
verified
D18:L8-BO
OSCs,
PCE
19.3%
20.1%,
among
highest
values
reported
OSCs.
Advanced Materials,
Год журнала:
2025,
Номер
unknown
Опубликована: Фев. 28, 2025
Abstract
Simultaneously
mitigating
both
photovoltage
and
photocurrent
losses
is
crucial
for
organic
solar
cells
(OSCs)
to
approach
the
Shockley–Queisser
limit
of
ideal
efficiency.
Incorporating
a
narrower
bandgap
nonfullerene
acceptor
(NFA)
as
guest
component
into
host
donor:NFA
system
broadens
absorption
spectrum.
However,
this
can
also
increase
nonradiative
decay
rate
according
energy‐gap
law.
In
work,
ternary
OSCs
are
constructed
by
combining
narrow
AQx‐2F
(as
NFA)
with
lower
eC9
NFA),
significantly
enhancing
generation
without
compromising
photovoltage.
The
addition
acts
crystallization
inducer,
extending
period
increasing
ordered
packing
distance.
This
leads
suppressed
trap
states,
elevated
dielectric
constant,
prolonged
exciton
lifetime,
balanced
hole/electron
transport,
reduced
recombination
loss.
Consequently,
optimized
D18:AQx‐2F:eC9
achieve
champion
power
conversion
efficiency
(PCE)
20.6%
high
open‐circuit
voltage
0.937
V,
short‐circuit
current
density
27.2
mA
cm
−2
fill
factor
80.8%,
validated
an
independently
certified
PCE
20.0%,
establishing
new
benchmark
bulk
heterojunction
OSCs.
work
demonstrates
effective
method
simultaneously
mitigate
losses,
paving
way
high‐performance
Advanced Materials,
Год журнала:
2025,
Номер
unknown
Опубликована: Янв. 6, 2025
The
long
exciton
diffusion
length
(LD)
plays
an
important
role
in
promoting
dissociation,
suppressing
charge
recombination,
and
improving
the
transport
process,
thereby
performance
of
organic
solar
cells
(OSCs),
especially
thick-film
OSCs.
However,
limited
LD
hinders
further
improvement
device
as
film
thickness
increases.
Here,
organic-metal
platinum
complex,
namely
TTz-Pt,
is
synthesized
served
a
solid
additive
into
D18-Cl:L8-BO
system.
addition
TTz-Pt
enhanced
crystallinity
blends,
reduced
energy
disorder,
trap
density,
decreased
non-radiative
recombination
binding
energy,
which
conducive
to
prolonging
TTz-Pt-treated
film,
facilitating
dissociation
process
along
with
inhibiting
recombination.
Consequently,
D18:L8-BO:IDIC
(100
nm)
exhibits
champion
power
conversion
efficiency
(PCE)
20.12%
(certified
19.54%),
one
highest
PCEs
reported
for
OSCs
date.
Remarkably,
record-breaking
PCE
18.84%
yielded
active
layer
300
nm.
Furthermore,
superior
universality
This
work
provides
simple
universal
approach
extending
by
introducing
complex
achieve
highly
efficient
ACS Applied Materials & Interfaces,
Год журнала:
2025,
Номер
unknown
Опубликована: Янв. 15, 2025
The
growing
advancement
of
wearable
technologies
and
sophisticated
sensors
has
driven
the
need
for
environmentally
friendly
reliable
energy
sources
with
robust
mechanical
stability.
Flexible
organic
solar
cells
(OSCs)
have
become
promising
substitutes
traditional
solutions
thanks
to
their
remarkable
flexibility
high
power
conversion
efficiency
(PCE).
These
unique
properties
allow
flexible
OSCs
seamlessly
integrate
diverse
devices
substrates,
making
them
an
excellent
choice
powering
various
electronic
by
efficiently
harvesting
energy.
This
review
summarizes
recent
achievements
in
from
perspective
self-powered
applications.
It
discusses
advancements
materials,
including
substrates
transparent
electrodes,
evaluates
performance
criteria,
compares
PCEs
rigid
counterparts.
Subsequently,
novel
applications
are
explored.
Finally,
a
summary
perspectives
on
current
challenges
obstacles
facing
wearables
provided,
aiming
inspire
further
research
toward
practical
implementations.
ACS Energy Letters,
Год журнала:
2024,
Номер
9(9), С. 4209 - 4217
Опубликована: Авг. 1, 2024
Improving
the
uniformity
and
density
of
self-assembled
monolayers
(SAMs)
is
crucial
to
elevate
photovoltaic
performance
organic
solar
cells
(OSCs).
Herein,
we
introduced
small
molecules
1-hydroxybenzotriazole
(HOBT)
modulate
distribution
electrical
properties
(4-(7H-dibenzo[c,g]carbazol-7-yl)butyl)phosphonic
acid
(4PADCB)
on
indium
tin
oxide
(ITO)
transparent
electrodes
in
an
innovative
manner.
The
hydroxyl
group
HOBT
interacts
with
phosphate
SAMs,
while
steric
repulsion
exerted
by
backbone
efficiently
regulates
SAMs.
This
led
a
more
uniform
dense
SAMs
ITO.
Furthermore,
HOBT-modified
have
improved
crystallization
vertical
phase
separation
upper
active
layer.
Consequently,
PM6:BTP-eC9
binary
OSCs
based
exhibit
impressive
PCE
19.66%.
Our
work
presents
effective
strategy
for
regulating
SAM
morphology
offers
promising
approach
advancing
OSCs.
Abstract
The
power
conversion
efficiency
of
organic
solar
cells
(OSCs)
is
exceeding
20%,
an
advance
in
which
morphology
optimization
has
played
a
significant
role.
It
generally
accepted
that
the
processing
solvent
(or
mixture)
can
help
optimize
morphology,
impacting
OSC
efficiency.
Here
we
develop
OSCs
show
strong
tolerance
to
range
solvents,
with
all
devices
delivering
high
efficiencies
around
19%.
By
investigating
solution
states,
film
formation
dynamics
and
characteristics
processed
films
both
experimentally
computationally,
identify
key
factors
control
is,
interactions
between
side
chains
acceptor
materials
as
well
donor
materials.
Our
work
provides
new
understanding
on
long-standing
question
effective
guides
design
towards
practical
applications,
where
green
solvents
are
required
for
large-scale
processing.
Advanced Materials,
Год журнала:
2024,
Номер
36(41)
Опубликована: Авг. 12, 2024
Abstract
Dipole
moment
arrangement
in
organic
semiconductors
plays
a
critical
role
affecting
the
intermolecular
packing,
determining
optoelectronic
properties
and
device
performance.
Here,
to
get
desired
fill
factor
(FF)
values
solar
cells
(OSCs),
local
dipole
of
non‐fullerene
acceptors
(NFAs)
is
modulated
by
changing
molecular
asymmetries.
Two
NFAs,
AA‐1
AA‐2
are
designed
synthesized,
which
have
different
substitutions
alkyl
alkoxyl
groups.
The
unidirectional
asymmetry
creates
distinct
dipoles,
while
bidirectional
mitigates
variation.
Despite
minimal
impact
on
monomolecular
properties,
significantly
influences
terminal
group
packing
modes
film
state.
This,
turn,
enhances
relative
dielectric
constant,
prolongs
exciton
lifetime,
reduces
sub‐bandgap
defect
states.
Consequently,
PBDB‐TF:AA‐2‐based
OSCs
achieve
an
exceptional
FF
0.830
power
conversion
efficiency
(PCE)
18.3%,
with
ternary
reaching
PCE
19.3%.
This
work
highlights
potential
modulation
material
design
ideal
for
high‐performance
OSCs.
Advanced Materials,
Год журнала:
2024,
Номер
unknown
Опубликована: Дек. 10, 2024
Abstract
All‐polymer
organic
solar
cells
(OSCs)
have
shown
unparalleled
application
potential
in
the
field
of
flexible
wearable
electronics
recent
years
due
to
excellent
mechanical
and
photovoltaic
properties.
However,
small
molecule
acceptors
after
polymerization
still
retain
some
aggregation
properties
molecule,
falling
short
ductility
requirements
for
devices.
Here,
based
on
multimodal
energy
dissipation
theory,
devices
are
co‐enhanced
by
adding
thermoplastic
elastomer
material
(polyurethane,
PU)
PM6:PBQx‐TF:PY‐IT‐based
active
layer
films.
The
construction
multi‐fiber
network
structure
decrease
films’
residual
stresses
contribute
enhancement
carrier
transport
defect
state
density.
Eventually,
PCE
(power
conversion
efficiency)
19.40%
is
achieved
with
an
effective
area
0.102
cm
2
,
third‐party
certified
reaches
19.07%,
which
highest
OSCs
currently
available.
To
further
validate
this
strategy
large‐area
module
applications,
25‐cm
‐based
super‐flexible
modules
prepared
PCEs
15.48%
14.61%,
respectively,
demonstration
applications
implemented.
