Chemistry - An Asian Journal,
Journal Year:
2025,
Volume and Issue:
unknown
Published: April 9, 2025
Abstract
MXene
is
a
cationic
2D
material
made
of
transition
metal
carbides
known
for
its
diverse
structure
and
multifunctionality.
It
faces
challenges
like
stacking,
oxidation,
weak
mechanical
properties
that
limit
use.
By
integrating
with
self‐supporting
porous
materials,
it
can
be
stabilized
converted
from
fragile
sheets
to
strong
3D
structures.
Wood,
due
natural
stability,
ideal
depositing
MXene,
which
adheres
wood
via
adsorption,
hydrogen
bonding,
or
reactions
fibers.
New
MXene‐wood
composites
improved
functions
have
been
created
show
great
potential
interdisciplinary
research.
This
review
covers
preparation
methods,
applications,
development,
composites,
aiming
provide
research
framework
progressive
direction
their
future
development.
Chemical Science,
Journal Year:
2024,
Volume and Issue:
15(29), P. 11229 - 11266
Published: Jan. 1, 2024
This
paper
reviews
advancements
in
flexible
carbon-based
and
polymer
gel
materials
for
various
types
of
energy
storage
systems,
providing
guidance
future
development
next-generation
wearable
electronics.
Advanced Materials,
Journal Year:
2025,
Volume and Issue:
unknown
Published: Jan. 5, 2025
Textiles
have
played
a
pivotal
role
in
human
development,
evolving
from
basic
fibers
into
sophisticated,
multifunctional
materials.
Advances
material
science,
nanotechnology,
and
electronics
propelled
next-generation
textiles
beyond
traditional
functionalities,
unlocking
innovative
possibilities
for
diverse
applications.
Thermal
management
incorporate
ultralight,
ultrathin
insulating
layers
adaptive
cooling
technologies,
optimizing
temperature
regulation
dynamic
extreme
environments.
Moisture
utilize
advanced
structures
unidirectional
transport
breathable
membranes,
ensuring
exceptional
comfort
activewear
outdoor
gear.
Protective
exhibit
enhanced
features,
including
antimicrobial,
antiviral,
anti-toxic
gas,
heat-resistant,
radiation-shielding
capabilities,
providing
high-performance
solutions
healthcare,
defense,
hazardous
industries.
Interactive
integrate
sensors
monitoring
physical,
chemical,
electrophysiological
parameters,
enabling
real-time
data
collection
responses
to
various
environmental
user-generated
stimuli.
Energy
leverage
triboelectric,
piezoelectric,
hygroelectric
effects
improve
energy
harvesting
storage
wearable
devices.
Luminous
display
textiles,
electroluminescent
fiber
optic
systems,
enable
visual
applications
fashion
communication.
These
advancements
position
at
the
forefront
of
materials
significantly
expanding
their
potential
across
wide
range
Abstract
The
development
of
wearable
energy
sto
rage
and
harvesting
devices
is
pivotal
for
advancing
next-generation
healthcare
technologies,
facilitating
continuous
real-time
health
monitoring.
Traditional
have
been
constricted
by
bulky
rigid
batteries,
limiting
their
practicality
comfort.
However,
recent
advancements
in
materials
science
enabled
the
creation
flexible,
stretchable,
lightweight
storage
solutions.
integration
technologies
essential
developing
self-sustaining
systems
that
minimize
reliance
on
external
power
sources
enhance
device
longevity.
These
integrated
ensure
operation
sensors
processors
vital
This
review
examines
significant
progress
harvesting,
focusing
latest
devices,
solar
cells,
biofuel
triboelectric
nanogenerators,
magnetoelastic
gene
rators,
supercapacitors,
lithium-ion
zinc-ion
batteries.
It
also
discusses
key
parameters
crucial
applications,
such
as
density,
durability.
Finally,
addresses
future
challenges
prospects
this
rapidly
evolving
field,
underscoring
potential
innovative,
self-powered
applications.
Graphical
Carbon Neutralization,
Journal Year:
2024,
Volume and Issue:
unknown
Published: Sept. 18, 2024
Abstract
Zinc
metal
stands
out
as
a
promising
anode
material
due
to
its
exceptional
theoretical
capacity,
impressive
energy
density,
and
low
redox
potential.
However,
challenges
such
zinc
dendrite
growth,
corrosion,
side
reactions
in
aqueous
electrolytes
significantly
impede
the
practical
application
of
anodes.
Herein,
3‐(1‐pyridinio)‐1‐propanesulfonate
(PPS)
is
introduced
zwitterionic
additive
achieve
long‐term
highly
reversible
Zn
plating/stripping.
Due
orientation
polarization
with
force
electric
field,
PPS
π–π
conjugated
pyridinio
cations
strong
coordination
ability
sulfonate
anion
tends
generate
dynamic
adsorption
layer
build
unique
water–poor
interface.
steric
hindrance
effect
can
attract
solvated
2+
,
thereby
promoting
desolvation
process.
Moreover,
by
providing
large
number
nucleation
sites
inducing
ion
flow,
preferred
(002)
crystal
plane
be
achieved.
Therefore,
interfacial
electrochemical
reduction
kinetics
regulated
uniform
deposition
ensured.
Owing
these
advantages,
Zn//Zn
symmetrical
cell
exhibits
remarkable
cycling
stability
exceeding
2340
h
(1
mA
cm
−2
1
).
The
Zn//V
2
O
5
full
also
delivers
stable
for
up
6000
cycles.
Solar RRL,
Journal Year:
2024,
Volume and Issue:
8(9)
Published: March 17, 2024
As
one
of
the
interface
engineering
methods
for
realizing
high‐performance
perovskite
solar
cells
(PSCs),
self‐assembled
monolayers
(SAMs)
with
hole‐transport
properties
have
recently
been
applied
as
an
effective
way
to
reduce
energy
losses
at
layer/perovskite
interface,
especially
in
PSCs
p–
i
–n
structure.
However,
there
are
still
limitations
implementing
PSC
high
efficiency
and
stability
due
inherent
weaknesses
single
SAMs.
Herein,
it
is
demonstrated
that
a
mixed
monolayer
appropriate
mixture
[2‐(3,6‐dimethoxy‐9
H
‐carbazol‐9‐yl)ethyl]phosphonic
acid
(MeO‐2PACz)
[4‐(3,6‐dimethyl‐9
‐carbazol‐9‐yl)butyl]phosphonic
(Me‐4PACz)
enables
simultaneous
improvement
PSCs.
In
SAM,
MeO‐2PACz
maintains
favorable
wettability
produce
high‐quality
films,
while
deep
highest
occupied
molecular
orbital
Me‐4PACz
optimizes
level
efficient
charge
transfer,
resulting
improved
performance.
Encouragingly,
mitigates
issues
MeO‐2PACz,
producing
SAM‐based
excellent
stability.
These
achieve
up
20.63%
exhibit
thermal
long‐term
stability,
retaining
90%
80%
their
initial
after
approximately
1400
2100
h
65
°C
N
2
atmosphere.
findings
suggest
potential
SAM
approaches
realization
Nanoscale,
Journal Year:
2024,
Volume and Issue:
16(18), P. 8778 - 8790
Published: Jan. 1, 2024
The
intermittent
nature
of
solar
energy
calls
for
integrated
cell-energy
storage
systems
that
combine
cells
with
various
devices.
This
review
summarizes
recent
advancements
in
these
systems,
including
design,
performance
evaluation
and
applications.