Advanced Materials,
Journal Year:
2024,
Volume and Issue:
36(15)
Published: Jan. 12, 2024
Perovskite
(PVSK)
photovoltaic
(PV)
devices
are
undergoing
rapid
development
and
have
reached
a
certified
power
conversion
efficiency
(PCE)
of
26.1%
at
the
cell
level.
Tremendous
efforts
in
material
device
engineering
also
increased
moisture,
heat,
light-related
stability.
Moreover,
solution-process
nature
makes
fabrication
process
perovskite
feasible
compatible
with
some
mature
high-volume
manufacturing
techniques.
All
these
features
render
solar
modules
(PSMs)
suitable
for
terawatt-scale
energy
production
low
levelized
cost
electricity
(LCOE).
In
this
review,
current
status
cells
(PSCs)
their
potential
applications
first
introduced.
Then
critical
challenges
identified
commercialization
propose
corresponding
solutions,
including
developing
strategies
to
realize
high-quality
films
over
large
area
further
improve
stability
meet
commercial
demands.
Finally,
directions
issues
requiring
attention
future,
mainly
focusing
on
dealing
toxicity
recycling
whole
device,
attainment
highly
efficient
perovskite-based
tandem
modules,
which
can
reduce
environmental
impact
accelerate
LCOE
reduction
put
forwarded.
Nature Communications,
Journal Year:
2024,
Volume and Issue:
15(1)
Published: March 12, 2024
Abstract
The
rapid
development
of
organic-inorganic
hybrid
perovskite
solar
cells
has
resulted
in
laboratory-scale
devices
having
power
conversion
efficiencies
that
are
competitive
with
commercialised
technologies.
However,
yet
to
make
an
impact
beyond
the
research
community,
translation
large-area
fabricated
by
industry-relevant
manufacturing
methods
remaining
a
critical
challenge.
Here
we
report
first
demonstration
cell
modules,
comprising
serially-interconnected
cells,
produced
entirely
using
industrial
roll-to-roll
printing
tools
under
ambient
room
conditions.
As
part
this
development,
costly
vacuum-deposited
metal
electrodes
replaced
printed
carbon
electrodes.
A
high-throughput
experiment
involving
analysis
batches
1600
20
parameter
combinations
enabled
optimisation
over
large
space.
optimised
show
up
15.5%
for
individual
small-area
and
11.0%
modules.
Based
on
work,
cost
~0.7
USD
W
−1
is
predicted
production
rate
1,000,000
m²
per
year
Australia,
potential
further
significant
reductions.
Nature Communications,
Journal Year:
2024,
Volume and Issue:
15(1)
Published: May 11, 2024
Can
Roll-to-Roll
technology
pave
the
way
for
perovskite
devices
to
transition
from
lab-scale
industrial
applications?
It
is
a
technique
that
has
potential
enhance
throughput,
reduce
costs,
and
accommodate
flexible
substrates.
In
system,
as
long
your
input
materials
are
continuously
topped
up,
manufacture
should
continue
indefinitely.
its
simplest
form
it
offers
premise
of
Ink-IN
/
Solar
module-OUT.
Through
this
comment,
we
emphasize
critical
need
ongoing
innovation
fully
harness
technology's
capabilities,
making
solar
energy
viable,
sustainable
option
on
global
scale.
(R2R)
coating
potentially
enhances
reduces
accommodates
substrates
fabricating
various
types
cells
modules.
Here,
authors
discuss
R2R
revolution
tackle
leap
photovoltaic
devices.
Advanced Science,
Journal Year:
2023,
Volume and Issue:
10(28)
Published: Aug. 4, 2023
As
a
key
contender
in
the
field
of
photovoltaics,
third-generation
thin-film
perovskite
solar
cells
(PSCs)
have
gained
significant
research
and
investment
interest
due
to
their
superior
power
conversion
efficiency
(PCE)
great
potential
for
large-scale
production.
For
commercialization
consideration,
low-cost
scalable
fabrication
is
primary
importance
PSCs,
development
applicable
film-forming
techniques
that
meet
above
requirements
plays
role.
Currently,
large-area
films
are
mainly
produced
by
printing
techniques,
such
as
slot-die
coating,
inkjet
printing,
blade
screen-printing.
Among
these
screen
offers
high
degree
functional
layer
compatibility,
pattern
design
flexibility,
ability,
showing
promise.
In
this
work,
advanced
progress
on
applying
screen-printing
technology
fabricating
PSCs
from
technique
fundamentals
practical
applications
presented.
The
introduced
state-of-the-art
studies
different
layers
control
strategies
realize
fully
screen-printed
summarized.
Moreover,
current
challenges
opportunities
faced
devices
discussed.
This
work
highlights
critical
significance
throughput
accelerating
course
products.
Advanced Materials,
Journal Year:
2023,
Volume and Issue:
36(17)
Published: Oct. 12, 2023
Abstract
Photovoltaic
technology
presents
a
sustainable
solution
to
address
the
escalating
global
energy
consumption
and
reliable
strategy
for
achieving
net‐zero
carbon
emissions
by
2050.
Emerging
photovoltaic
technologies,
especially
printable
organic
perovskite
solar
cells,
have
attracted
extensive
attention
due
their
rapidly
transcending
power
conversion
efficiencies
facile
processability,
providing
great
potential
revolutionize
market.
To
accelerate
these
technologies
translate
from
laboratory
scale
industrial
level,
it
is
critical
develop
well‐defined
scalable
protocols
deposit
high‐quality
thin
films
of
photoactive
charge‐transporting
materials.
Herein,
current
state
cells
summarized
view
regarding
challenges
prospects
toward
commercialization
shared.
Different
printing
techniques
are
first
introduced
provide
correlation
between
material
properties
mechanisms,
optimization
ink
formulation
film‐formation
during
large‐area
deposition
different
functional
layers
in
devices
then
discussed.
Engineering
perspectives
also
discussed
analyze
criteria
module
design.
Finally,
provided
future
development
practical
commercialization.
It
believed
that
this
perspective
will
insight
into
other
electronic
devices.
Advanced Energy Materials,
Journal Year:
2024,
Volume and Issue:
14(29)
Published: May 11, 2024
Abstract
The
demand
for
cost‐effective
and
rapid
processing
of
large‐area
thin
films
in
the
photovoltaic
industry
has
recently
driven
significant
research
interest.
In
this
context,
among
various
approaches
explored,
printing
devices,
particularly
perovskite
solar
cells
(PSCs),
have
garnered
considerable
attention
due
to
their
potential
scalability
cost
efficiency.
Besides,
solution
is
widely
recognized
as
an
appealing
strategy
large‐area,
cost‐effective,
high‐throughput
production
PSCs.
However,
while
substantial
progress
been
made
process,
challenges
related
stability,
uniformity,
remain
be
addressed.
This
review
critically
examines
key
techniques
substrates
employed
PSC
fabrication.
Then,
given
significance
ambient
air
industrial
applications,
fundamental
associated
with
achieving
PSCs
are
discussed
detail.
Moreover,
formulation
strategies
ink
technologies
thoroughly
considering
its
crucial
role
determining
performance
stability
printed
Finally,
process
components
PSCs,
including
absorber
layer,
charge
transport
layers
(CTLs),
electrodes,
meticulously
analyzed,
highlighting
current
achievements
remaining
hurdles.
ACS Applied Materials & Interfaces,
Journal Year:
2024,
Volume and Issue:
16(14), P. 17607 - 17616
Published: April 1, 2024
Perovskite
solar
cells
(PSCs)
offer
impressive
performance
and
flexibility,
thanks
to
their
simple,
low-temperature
deposition
methods.
Their
band
gap
tunability
allows
for
a
wide
range
of
applications,
transitioning
from
opaque
transparent
devices.
This
study
introduces
the
first
flexible,
bifacial
PSCs
using
FAPbBr3
perovskite.
We
investigated
impact
optimizing
electron
hole
transport
layers
on
cells'
bifaciality,
transparency,
stability.
achieved
maximum
power
conversion
efficiency
(PCE)
6.8
18.7%
under
1
sun
indoor
light
conditions
(1200
lx),
respectively,
showing
up
98%
bifaciality
factor
an
average
visible
transmittance
(AVT)
55%.
Additionally,
P1–P2–P3
laser
ablation
scheme
has
been
developed
flexible
poly(ethylene
terephthalate)
(PET)
substrate
perovskite
modules
PCE
4.8%
high
geometrical
fill
(97.8%).
These
findings
highlight
potential
diverse
applications
such
as
building-integrated
photovoltaics
(BIPV),
agrivoltaics,
automotive
technology,
wearable
sensors,
Internet
things
(IoT).
Solar RRL,
Journal Year:
2024,
Volume and Issue:
8(6)
Published: Jan. 26, 2024
Over
the
past
decade,
perovskite
solar
cells
(PSCs)
have
achieved
significant
achievements.
But
golden
triangle
problem
of
commercial
development,
which
encompasses
high
efficiency,
stability,
and
low
cost,
remains
unresolved.
Carbon
materials
exhibit
a
diverse
range
morphological
structures
possess
numerous
advantages.
They
are
extensively
used
in
PSCs
to
overcome
challenges
encountered
during
commercialization.
The
utilizing
graphene
as
top
electrodes
not
only
deliver
an
impressive
efficiency
22.8%,
but
also
show
exceptional
long‐term
stability.
using
carbon
nanotubes
transparent
conductive
obtain
19%,
exhibiting
potential
for
scalable
applications.
Herein,
advantages
overviewed.
compatibility
PSCs,
along
with
associated
challenges,
regulatory
strategies,
device
performance
systematically
discussed
terms
their
intrinsic
characteristics.
application
derived
from
petroleum
by‐products
biomass
summarized
detail.
Finally,
underlying
reasons
why
electrode
comparatively
lower
when
compared
conventional
devices
is
analyzed
in‐depth.
research
directions
proposed
promote
development
PSCs.
Solar RRL,
Journal Year:
2024,
Volume and Issue:
8(6)
Published: Jan. 25, 2024
Carbon
electrodes
have
gained
significant
attention
as
a
cost‐effective,
sustainable,
stable,
and
scalable
replacement
for
metal
in
perovskite
solar
cells
(PSCs).
However,
traditional
carbon‐electrode‐based
PSCs
(C‐PSCs)
lack
hole‐selective
layer
(HSL)
due
to
their
incompatibility
with
the
most
effective
organic
HSLs
employed
PSC
literature.
In
turn,
absence
of
an
HSL
has
been
identified
one
main
factors
hindering
performance
C‐PSCs.
Consequently,
numerous
studies
recognized
pivotal
significance
region
between
absorber
carbon
electrode
C‐PSCs,
proposing
various
interfacial
engineering
strategies
improve
these
cells.
Given
rapid
evolution
this
field,
up‐to‐date
comprehensive
review
C‐PSCs
is
order.
Key
areas
focus
include
shift
from
high‐temperature
low‐temperature
electrodes,
energetic
alignment
at
interface,
novel
approaches
such
bilayers,
alternative
deposition
methods
reduce
solvent
damage.
Additionally,
presents
meta‐analysis—the
first
its
kind
C‐PSC
literature—to
assess
how
modifications
impact
critical
metrics,
offering
valuable
insights
future
advancements
field.
