ACS ES&T Engineering,
Journal Year:
2023,
Volume and Issue:
3(12), P. 2147 - 2160
Published: July 20, 2023
Electro-Fenton-based
membrane
(EFM)
technologies
are
promising
for
removing
micropollutants
in
wastewater
bearing
several
benefits
such
as
minimized
chemical
input,
accelerated
reactive
oxygen
species
(ROS)
generation,
and
improved
ROS
utilization
efficiency,
thanks
to
the
enhanced
mass
transfer
effectively
enlarged
electroactive
area.
However,
complex
mechanism
synergies
between
electro-Fenton
reactions
confinement
remain
unclear;
gaining
information
would
be
much
beneficial
rational
catalyst/membrane
design,
system
optimization,
further
application
actual
water
conditions.
In
this
Perspective,
we
systematically
describe
compositions,
multiple
reaction
pathways,
advances
EFM
systems.
Then,
proposed
some
hybrid
systems
that
exhibit
great
maximizing
purification
efficiency.
Finally,
perspective
provides
a
roadmap
future
development
of
with
low
cost
high
efficiency
by
outlining
advanced
material
coupling
processes,
integrated
device
design.
Advanced Materials,
Journal Year:
2023,
Volume and Issue:
35(23)
Published: March 29, 2023
Various
metal
ions
with
different
valence
states
(Mg2+
,
Al3+
Ca2+
Ti4+
Mn2+
Fe3+
Ni2+
Zn2+
Pb2+
Ba2+
Ce4+
)
are
successfully
confined
in
quasi-microcube
shaped
cobalt
benzimidazole
frameworks
using
a
space-confined
synthesis
strategy.
More
importantly,
series
of
derived
carbon
materials
that
confine
obtained
by
high-temperature
pyrolysis.
Interestingly,
the
exhibited
electric
double-layer
and
pseudocapacitance
properties
because
presence
various
states.
Moreover,
additional
within
may
create
new
phases,
which
can
accelerate
Na+
insertion/extraction
thus
increase
electrochemical
adsorption.
Density
functional
theory
results
showed
Ti
exhibit
enhanced
resulting
from
characteristic
anatase
crystalline
phases
TiO2
.
The
Ti-containing
have
an
impressive
desalination
capacity
(62.8
mg
g-1
capacitive
deionization
(CDI)
applications
high
cycling
stability.
This
work
provides
facile
synthetic
strategy
for
confinement
metal-organic
supports
further
development
seawater
CDI.
Nano-Micro Letters,
Journal Year:
2023,
Volume and Issue:
15(1)
Published: Jan. 3, 2023
Efficient
bifunctional
catalysts
for
oxygen
reduction
reaction
(ORR)
and
evolution
(OER)
are
vital
rechargeable
Zn-air
batteries
(ZABs).
Herein,
an
oxygen-respirable
sponge-like
Co@C-O-Cs
catalyst
with
oxygen-rich
active
sites
was
designed
constructed
both
ORR
OER
by
a
facile
carbon
dot-assisted
strategy.
The
aerophilic
triphase
interface
of
cathode
efficiently
boosts
diffusion
transfer.
theoretical
calculations
experimental
studies
revealed
that
the
Co-C-COC
can
redistribute
local
charge
density
lower
energy
barrier.
displays
superior
catalytic
activities
half-wave
potential
0.82
V
ultralow
overpotential
294
mV
at
10
mA
cm-2
OER.
Moreover,
it
drive
liquid
ZABs
high
peak
power
(106.4
mW
cm-2),
specific
capacity
(720.7
mAh
g-1),
outstanding
long-term
cycle
stability
(over
750
cycles
exhibits
excellent
feasibility
in
flexible
all-solid-state
ZABs.
These
findings
provide
new
insights
into
rational
design
efficient
metal-air
batteries.
Advanced Materials,
Journal Year:
2023,
Volume and Issue:
35(11)
Published: Jan. 3, 2023
Supported
metal
catalysts
have
played
an
important
role
in
optimizing
selective
semihydrogenation
of
alkynes
for
fine
chemicals.
There
into,
nitrogen-doped
carbons,
as
a
type
promising
support
materials,
attracted
extensive
attentions.
However,
due
to
the
general
phenomenon
random
doping
nitrogen
species
support,
it
is
still
atremendous
challenge
finely
identify
which
configuration
dominates
catalytic
property
alkynes'
semihydrogenation.
Herein,
reported
that
uniform
mesoporous
N-doped
carbon
spheres
derived
from
polypyrrole
are
used
supports
immobilized
subnanometric
Pd
clusters,
provide
particular
platform
research
influence
configurations
on
Comprehensive
experimental
results
and
density
functional
theory
calculation
indicate
pyridinic
behavior
clusters.
The
high
contents
sites
offer
abundant
coordination
sites,
greatly
reduces
energy
barrier
rate-determining
reaction
step
makes
clusters
own
activity.
electron
effect
between
highly
selective.
Additionally,
good
mesostructures
also
promote
fast
transport
substrate.
Based
above,
catalyst
Pd@PPy-600
exhibits
activity
(99%)
selectivity
(96%)
phenylacetylene
(C8
H6
)
ACS Nano,
Journal Year:
2024,
Volume and Issue:
18(34), P. 22829 - 22854
Published: Aug. 17, 2024
Porous
materials,
characterized
by
their
controllable
pore
size,
high
specific
surface
area,
and
controlled
space
functionality,
have
become
cross-scale
structures
with
microenvironment
effects
multiple
functions
gained
tremendous
attention
in
the
fields
of
catalysis,
energy
storage,
biomedicine.
They
evolved
from
initial
nanopores
to
multiscale
pore-cavity
designs
yolk-shell,
multishells,
or
asymmetric
structures,
such
as
bottle-shaped,
multichambered,
branching
architectures.
Various
synthesis
strategies
been
developed
for
interfacial
engineering
porous
including
bottom-up
approaches
using
liquid-liquid
liquid-solid
interfaces
"templating"
top-down
toward
chemical
tailoring
polymers
different
cross-linking
degrees,
well
interface
transformation
Oswald
ripening,
Kirkendall
effect,
atomic
diffusion
rearrangement
methods.
These
techniques
permit
design
functional
materials
diverse
effects,
size
enrichment
isolation
synergistic
local
field
enhancement
enhanced
applications.
In
this
review,
we
delve
into
interfacial-oriented
advanced
effects.
We
also
discuss
recent
progress
applications
these
collaborative
structure-activity
relationships
areas
electrochemical
conversion,
Finally,
outline
persisting
obstacles
prospective
avenues
terms
functionalization
engineering.
The
perspectives
proposed
paper
may
contribute
promote
wider
various
interdisciplinary
within
confined
dimensions
structures.
Advanced Materials,
Journal Year:
2024,
Volume and Issue:
36(28)
Published: April 30, 2024
Abstract
Ultrasmall
mesoporous
nanoparticles
(<50
nm),
a
unique
porous
nanomaterial,
have
been
widely
studied
in
many
fields
the
last
decade
owing
to
abundant
advantages,
involving
rich
mesopores,
low
density,
high
surface
area,
numerous
reaction
sites,
large
cavity
space,
ultrasmall
size,
etc.
This
paper
presents
review
of
recent
advances
preparation,
functionalization,
and
applications
inorganic
for
first
time.
The
soft
monomicelles‐directed
method,
contrast
hard‐template
template‐free
methods,
is
more
flexible
synthesis
nanoparticles.
because
amphiphilic
micelle
has
tunable
functional
blocks,
controlled
molecule
masses,
configurations
mesostructures.
Focus
on
directing
monomicelles
could
be
classified
into
four
types,
i.e.,
Pluronic‐type
block
copolymer
monomicelles,
laboratory‐synthesized
copolymers
single‐molecule
star‐shaped
small‐molecule
anionic/cationic
surfactant
monomicelles.
also
reviews
functionalization
inner
mesopores
outer
surfaces,
which
includes
constructing
yolkshell
structures
(encapsulated
nanoparticles),
anchoring
active
components
packed
shell
building
an
asymmetric
Janus
architecture.
Then,
several
representative
applications,
catalysis,
energy
storage,
biomedicines
are
presented.
Finally,
prospects
challenges
large‐scale
future
foreseen.
Small,
Journal Year:
2024,
Volume and Issue:
20(26)
Published: Jan. 17, 2024
The
unique
properties
of
high
entropy
alloy
(HEA)
catalysts,
particularly
their
severe
lattice
distortion
and
the
synergistic
effect
multiple
components,
endow
them
with
exceptional
multifunctional
catalytic
performance.
Herein,
it
is
revealed
for
first
time,
that
ultrasmall
PtRhNiFeCu
HEA
nanoparticles
catalyst
shows
outstanding
activity
both
hydrogen
evolution
reaction
(HER)
oxygen
reduction
(ORR).
exhibits
an
impressively
low
overpotential
13
mV
at
10
mA
cm
ACS Nano,
Journal Year:
2024,
Volume and Issue:
18(27), P. 17901 - 17912
Published: June 24, 2024
Modulating
the
energy
barrier
of
reaction
intermediates
to
surmount
sluggish
kinetics
is
an
utterly
intriguing
strategy
for
amplifying
oxygen
reduction
reaction.
Herein,
a
Cu3P/CoP
hybrid
incorporated
on
hollow
porous
N-doped
carbon
nanospheres
via
dopamine
self-polymerization
and
high-temperature
treatment.
The
resultant
Cu3P/CoP@NC
showcases
favorable
mass
activity
4.41
mA
mg–1
kinetic
current
density
2.38
cm–2.
Strikingly,
catalyst
endows
aqueous
Zn-air
battery
(ZAB)
with
large
power
209.0
mW
cm–2,
superb
cyclability
over
317
h,
promising
application
prospects
in
flexible
ZAB.
Theoretical
simulations
reveal
that
Cu
functions
as
modulator
modify
free
adsorbs
O2
Co
sites,
hence
rushing
kinetics.
open
hydrophilic
spherical
mesoporous
structure
provides
unimpeded
channels
reactant
diffusion
electrolyte
penetration,
whereas
exposed
inner
outer
surfaces
can
confer
plethora
accessible
actives
sites.
This
research
establishes
feasible
design
concept
tune
catalytic
non-noble
metal
materials
by
construction
rational
nanoframework.
Advanced Functional Materials,
Journal Year:
2025,
Volume and Issue:
unknown
Published: Jan. 12, 2025
Abstract
Microwave
absorption
materials
play
a
key
role
in
various
fields,
including
military
stealth,
human
safety
protection,
and
so
on.
Construction
of
2D
mesoporous
heterostructures
is
an
attractive
approach
to
enhance
wave‐absorbing
ability,
while
it
still
great
challenge.
Herein,
carbon‐MXene‐carbon
(MCMCH)
with
channels
parallel
surface
are
successfully
prepared
via
monolayer
interfacial
assembly
strategy.
Through
the
precise
adjustment
polymerization,
cylindrical
micelles
orderly
monolayered
assemble
on
both
surfaces
MXene
nanosheets,
resulting
switch‐like
polydopamine‐MXene‐polydopamine
MCMCH
finally
generated
by
further
calcination.
Due
excellent
dielectric
polarization
relaxation
conductive
loss,
achieves
strongest
reflection
loss
−54.2
dB
at
thickness
only
1.5
mm.
The
presence
mesochannels
not
introduces
air
low
permittivity
for
optimal
impedance
matching,
but
also
extends
attenuation
path
incident
electromagnetic
wave.
maximum
radar
cross‐section
reduction
26.9
m
2
achieved
compared
perfect
electric
conductor.
This
work
provides
reference
engineering
based
microwave
performance.
