Advancements in 2D Titanium Carbide (MXene) for Electromagnetic Wave Absorption: Mechanisms, Methods, Enhancements, and Applications
Small Methods,
Journal Year:
2025,
Volume and Issue:
unknown
Published: Jan. 28, 2025
Abstract
With
the
advent
of
5G
era,
there
has
been
a
marked
increase
in
research
interest
concerning
electromagnetic
wave‐absorbing
materials.
A
critical
challenge
remains
improving
properties
these
materials
while
satisfying
diverse
application
demands.
MXenes,
identified
as
prominent
“emerging”
2D
for
wave
absorption,
offer
unique
advantages
that
are
expected
to
drive
advancements
and
innovations
this
field.
This
review
emphasizes
synthesis
benefits
provided
by
structural
characteristics
MXenes
performance
enhancements
achieved
through
their
combination
with
other
absorbing
Material
requirements,
approaches,
conceptual
frameworks
integrated
underscore
advantages.
The
study
provides
thorough
analysis
MXene‐absorbing
composites,
going
beyond
basic
classification
address
preparation
modification
processes
affecting
absorption
composites.
Attention
is
directed
techniques,
design
principles,
influence
on
composite
performance.
Additionally,
potential
applications
devices
summarized.
concludes
addressing
challenges
currently
confronting
MXene
outlining
developmental
trends,
aiming
guidance
subsequent
domain.
Language: Английский
Flexible Ti3C2Tx MXene Film Coupled with Defect‐Rich MoO3 Spacer‐Contributor toward High‐Performance Wearable Energy Storage
Small,
Journal Year:
2025,
Volume and Issue:
unknown
Published: March 3, 2025
Abstract
MXene
film‐derived
flexible
supercapacitors
have
shown
great
application
foreground
for
wearable
electronics,
but
the
capacitive
characteristics,
especially
when
faced
with
mechanical
deformations,
are
not
satisfactory.
Herein,
a
new
kind
of
electrode,
MX/D‐MoO
3
,
is
developed
by
using
Ti
C
2
T
x
film
(MX)
and
defect‐rich
MoO
(D‐MoO
)
as
“main
body”
“spacer‐contributor”,
respectively.
Results
indicate
that,
D‐MoO
intercalation,
notably
enlarged
layer
spacing
nanosheets
boosted
electrochemical
active
sites
fulfilled,
which
facilitated
wondrous
property
increases
342%
239%
compared
to
raw
MX
MX/MoO
Particularly,
‐60
has
high
specific
capacitance
2734.3
mF
cm
−2
at
1
mA
surpasses
most
counterparts
reported
thus
far.
The
‐60‐based
all‐solid‐state
supercapacitor
presents
largest
energy
density
96.3
µWh
205.9
µW
an
outstanding
power
1871.4
18.6
.
Meanwhile,
impressive
stability
retention
91.8%
after
5
000
cycles
flexibility
90.3%
under
bending
angles
from
0
180°
also
exhibited.
superior
properties
facile
preparation
endow
promising
applications
in
storage.
Language: Английский
Recent advances in multiple transition metal MXenes: Synthesis, properties, and applications in energy storage
Sheng Zhou,
No information about this author
Yunfeng Guan,
No information about this author
Lidan Tan
No information about this author
et al.
Journal of Energy Storage,
Journal Year:
2025,
Volume and Issue:
120, P. 116419 - 116419
Published: April 7, 2025
Language: Английский
An editable yarn-based flexible supercapacitor and integrated self-powered sensor
Qiancheng Ma,
No information about this author
Zhaofa Zhang,
No information about this author
Lin Li
No information about this author
et al.
Science China Materials,
Journal Year:
2025,
Volume and Issue:
unknown
Published: Feb. 28, 2025
Language: Английский
Enhancing Electrochemical Energy Storage with 3D Ti3C2Tx Hybrid Electrode Materials
Kai Song,
No information about this author
Jiabei Li,
No information about this author
Tursun Abdiryim
No information about this author
et al.
Advanced Functional Materials,
Journal Year:
2025,
Volume and Issue:
unknown
Published: May 23, 2025
Abstract
MXenes
have
demonstrated
significant
promise
in
electrochemical
energy
storage
due
to
their
high
electrical
conductivity,
excellent
flexibility,
and
hydrophilicity.
However,
susceptibility
stacking
oxidation
limits
the
development
of
storage.
In
this
paper,
3D
structured
Ti
3
C
2
T
x
(THM)
is
prepared.
Subsequently,
THM
used
as
inner
support
structure,
polydopamine
(PDA)
outer
shell
structure
encapsulate
THM,
uniformly
dispersed
N‐doped
spherical
(THM@CN)
obtained
after
carbonization
at
650
°C.
Finally,
NiS
cultivated
on
surface
THM@CN
by
hydrothermal
synthesis
acquire
electrode
material
NiS/THM@CN.
The
NiS/THM@CN
has
a
weight
capacitance
2750
F
g
−1
(305.56
mAh
/1
A
).
Furthermore,
solid‐phase
asymmetric
HSC
an
density
up
73.36
Wh
kg
and,
with
system,
sustained
88.5%
initial
value
15
000
cycles.
proposed
junction
CN
specific
area
dispersion,
well
stability,
which
further
promotes
application
high‐performance
devices.
Language: Английский