ACS Applied Materials & Interfaces,
Journal Year:
2023,
Volume and Issue:
15(34), P. 41180 - 41192
Published: Aug. 16, 2023
In
order
to
address
the
requirements
for
warmth
and
energy
conservation
in
cold
climates,
development
of
personal
thermal
management
textiles
that
regulate
local
human
comfort
has
emerged
as
a
promising
solution
recent
times.
Nevertheless,
existing
warming
textile
strategies
often
rely
on
singular
source,
exhibit
inadequate
air/moisture
permeability,
lack
adaptability
dynamic
intricate
climate
variations.
Herein,
novel
multienergy-coupled
radiative
Janus
been
effectively
designed
fabricated
via
screen
printing
foam
finishing.
Taking
advantage
synergistic
effects
directional
water
transport
capability
polyester-covered
cotton
(with
water-transport
index
R
=
577.5%),
high
mid-infrared
radiant
reflection
(at
60%),
electrothermal
conversion
copper
coating
sheet
resistance
0.01
Ω
sq-1),
strong
solar
absorption
nanoporous
structure
TA@APTES@Fe(III)@CNT
(TAFC)
98.5%),
fabric
exhibits
exceptional
performance
expelling
out
one-way
sweat/moisture
(R
329.3%)
heating
(86.9
°C)/Joule
(226.4
°C
at
3.0
V)/heat
retention
(2.4
higher
than
fabric).
Furthermore,
is
also
provided
with
mechanical,
washing,
flame-retardant,
antibacterial
performance.
This
research
holds
potential
revolutionize
production
by
incorporating
desirable
permeability
heating.
ACS Applied Nano Materials,
Journal Year:
2024,
Volume and Issue:
7(4), P. 3748 - 3760
Published: Feb. 5, 2024
As
wearable
electronics
and
medical
implants
evolve,
there
is
an
increasing
demand
for
protective
devices
that
provide
both
electromagnetic
interference
(EMI)
shielding
heating
capabilities
while
operating
at
weaker
voltages
to
accommodate
various
power
sources.
Herein,
a
simple,
cost-friendly,
step-by-step
vacuum-assisted
filtration
method
utilized
prepare
asymmetrical
layered
"MXene–MXene@silver
nanowires(AgNWs)-MXene-AgNWs"
hybrid
films,
exhibiting
"mille-feuille"-like
structure
with
thickness
of
9.02
μm,
possessing
enhanced
flexibility
suitable
applications.
This
composite
exploits
the
excellent
electrical
thermal
conductivity
AgNWs
together
notable
EMI
performance
MXene
(SE/t
=
112,967
dB
cm–1
).
By
tuning
layer
AgNW
framework,
multilayer
structured
film
achieves
effectiveness
68,825
cm–1).
Due
introduction
layer,
its
interface
reflection
properties
lead
differential
wave
(EMW)
consumption
in
structure,
resulting
62.08
dB.
The
attributed
reflection,
which
significantly
increases
effective
pathway
incident
EMWs.
Moreover,
Joule
reaches
227.7
°C
1.0
V,
superior
ultralow
voltage
drive
characteristic.
flexible
self-supported
has
significant
potential
applications
protecting
human
body
implants,
such
as
cardiac
pacemakers,
from
influence
pollution.
Furthermore,
it
can
be
extreme
weather
conditions
deicing,
defogging,
antifreezing
purposes.
Advanced Functional Materials,
Journal Year:
2024,
Volume and Issue:
unknown
Published: Sept. 17, 2024
Abstract
An
intelligent
process
for
developing
electromagnetic
interference
(EMI)
shielding
composites
is
imperative
to
eliminate
the
escalating
pollution
of
waves
(EMWs).
Meanwhile,
integrating
porous
and/or
layered
structures
with
polymers
demonstrated
as
an
effective
approach.
Herein,
expert
knowledge
serves
guidance
Simulation‐First
Strategy
in
designing
that
incorporate
MXene
bubble
wrap‐like
aerogels
(MB
a‐b
A),
characterized
by
distinct
diameters
a
and
densities
b
.
The
simulated
EMI
efficiency
(EMI
SE)
corresponding
MB
A/polyethylene
glycol
AP)
predicted
through
finite
element
analysis
(FEA)
simulation.
Subsequently,
AP
are
fabricated
template
methods
exhibit
outstanding
SE
up
83.1
dB
ultrahigh
absorption
(SE
A
)
75.1
X
band
at
=
10
µm
0.50,
perfectly
aligning
simulation
outcomes.
Combined
macro‐scale
FEA
experimental
evidence,
pronounced
EMWs
attenuation
effect,
heat
storage/release,
mechanical
performances
unequivocally
substantiated.
Based
on
these,
this
work
proves
feasibility
development
strategy
provides
research
basis
advanced
materials
directed
knowledge.
ACS Applied Materials & Interfaces,
Journal Year:
2023,
Volume and Issue:
15(34), P. 41180 - 41192
Published: Aug. 16, 2023
In
order
to
address
the
requirements
for
warmth
and
energy
conservation
in
cold
climates,
development
of
personal
thermal
management
textiles
that
regulate
local
human
comfort
has
emerged
as
a
promising
solution
recent
times.
Nevertheless,
existing
warming
textile
strategies
often
rely
on
singular
source,
exhibit
inadequate
air/moisture
permeability,
lack
adaptability
dynamic
intricate
climate
variations.
Herein,
novel
multienergy-coupled
radiative
Janus
been
effectively
designed
fabricated
via
screen
printing
foam
finishing.
Taking
advantage
synergistic
effects
directional
water
transport
capability
polyester-covered
cotton
(with
water-transport
index
R
=
577.5%),
high
mid-infrared
radiant
reflection
(at
60%),
electrothermal
conversion
copper
coating
sheet
resistance
0.01
Ω
sq-1),
strong
solar
absorption
nanoporous
structure
TA@APTES@Fe(III)@CNT
(TAFC)
98.5%),
fabric
exhibits
exceptional
performance
expelling
out
one-way
sweat/moisture
(R
329.3%)
heating
(86.9
°C)/Joule
(226.4
°C
at
3.0
V)/heat
retention
(2.4
higher
than
fabric).
Furthermore,
is
also
provided
with
mechanical,
washing,
flame-retardant,
antibacterial
performance.
This
research
holds
potential
revolutionize
production
by
incorporating
desirable
permeability
heating.
