Abstract
The
review
provides
an
overview
of
the
latest
innovations,
trends,
and
challenges
in
field
3D‐printed
metal
metal‐ion
batteries.
It
focuses
on
materials
used
printing
batteries,
including
electrodes,
electrolytes,
other
electroactive
components.
Compared
to
high‐quality
reviews
topic,
this
a
broader
selection
that
are
expected
gain
attention
next
few
years,
such
as
redox‐active
polymers
metal‐organic
frameworks.
This
work
gives
insight
into
trends
techniques
well
statistical
their
uses
strengths.
We
have
also
gathered
works
done
for
each
material
types,
we
taken
opportunity
put
them
context
use
exemplify
which
direction
is
going.
concludes
with
critical
view
ahead
discussion
taking
external
factors
might
help
define
its
future.
Abstract
The
development
and
application
of
lithium‐ion
batteries
present
a
dual
global
prospect
opportunity
challenge.
With
conventional
energy
sources
facing
reserve
shortages
environmental
issues,
have
emerged
as
transformative
technology
over
the
past
decade,
owing
to
their
superior
properties.
They
are
poised
for
exponential
growth
in
realms
electric
vehicles
storage.
cathode,
vital
component
batteries,
undergoes
chemical
electrochemical
reactions
at
its
surface
that
directly
impact
battery's
density,
lifespan,
power
output,
safety.
Despite
increasing
density
cathodes
commonly
encounter
surface‐side
with
electrolyte
exhibit
low
conductivity,
which
hinder
utility
high‐power
energy‐storage
applications.
Surface
engineering
has
compelling
strategy
address
these
challenges.
This
paper
meticulously
examines
principles
progress
cathode
materials,
providing
insights
into
potential
advancements
charting
trajectory
practical
implementation.
Advanced Energy Materials,
Год журнала:
2024,
Номер
14(39)
Опубликована: Июль 10, 2024
Abstract
Lithium–sulfur
(Li–S)
batteries
can
offer
high
capacity
and
energy‐density,
but
face
challenges
like
low
conductivity,
lithium
polysulfides
(LiPSs)
shuttling,
limited
reaction
kinetics.
In
this
study,
the
electronic
configuration
of
Mo
4d
orbital
in
MoS
2
is
modulated
through
a
one‐step
method
involving
tungstate
anion
(WO
4
2−
)
modulation
to
form
stable
1T‐MoS
/carbon
composite
(1T‐W‐MoS
/C).
When
WO
introduced,
it
causes
transfer
electrons
2H‐MoS
,
resulting
generation
1T
phase.
composite,
nanosheets
exhibit
remarkable
hydrophilicity,
catalytic
activity,
facilitating
LiPSs
adsorption
Li
+
transport.
Meanwhile,
create
abundant
adsorption/catalytic
sites
with
defects
on
basal
surface
edges
efficient
catalysis
conversion.
Furthermore,
3D‐printed
electrodes
without
utilization
binders
current
collectors
ensure
mass
loading
promote
ion
diffusion
electrolyte
penetration.
Theoretical
experimental
results
confirm
that
1T‐W‐MoS
/C
catalyze
conversion,
suppress
enhance
sulfur
Therefore,
/C/S
cathode
exhibits
initial
excellent
rate
capability,
achieving
an
areal
7.37
mAh
cm
−2
8.89
mg
.
Applied Physics Reviews,
Год журнала:
2024,
Номер
11(4)
Опубликована: Ноя. 5, 2024
Additive
manufacturing,
commonly
known
as
3D
printing,
is
an
innovative
technique
for
fabricating
batteries
with
arbitrary
architectures.
Understanding
the
intricacies
of
printing
designs
in
sodium
battery
materials
crucial
optimizing
their
electrochemical
properties
and
unlocking
full
potential
printed
batteries.
This
review
provides
a
comprehensive
overview
key
aspects
involved
fabrication
batteries,
encompassing
material
selectivity
criterion,
design
considerations,
optimization
strategies.
Challenges
prospects
high-performance
are
outlined,
aiming
to
provide
valuable
insights
into
new
conception
theoretical
guidance
performance
composites
by
practical
application
future.
Advanced Functional Materials,
Год журнала:
2025,
Номер
unknown
Опубликована: Март 27, 2025
Abstract
In
recent
years,
secondary
batteries
have
emerged
as
a
hot
research
area,
with
electrodes
being
one
of
the
key
components
that
significantly
impact
battery
performance.
However,
traditional
coating‐type
electrode
sheets,
which
limitations
in
terms
energy
and
power
density,
can
no
longer
satisfy
current
demands
for
batteries.
3D
printing
technology,
known
its
low
cost,
simple
operation,
rapid
prototyping,
ease
customization,
has
garnered
widespread
attention.
By
applying
technology
to
optimizing
their
structure
design,
it
is
possible
create
more
active
sites
ion/charge
transport
channels,
thereby
enhancing
electrochemical
performance
Herein,
this
paper
reviews
currently
commonly
used
storage
technologies
standards
ink
formulation.
A
variety
representative
printed
structures
optimization
strategies
are
also
listed.
addition,
materials
use,
ranging
from
0D
3D,
covered,
including
synthesis
methods,
morphology,
contributions
It
anticipated
review
will
provide
valuable
insights
into
rapidly
developing
field.
Advanced Functional Materials,
Год журнала:
2024,
Номер
unknown
Опубликована: Май 7, 2024
Abstract
The
burgeoning
field
of
energy
storage
battery
innovation
has
sparked
a
relentless
pursuit
high‐capacity
anode
materials
to
meet
the
escalating
demand
for
improved
density.
Typically,
these
batteries
experience
significant
volume
changes
during
cycles,
which
severely
test
structural
integrity
and
lifespan
electrode
configurations.
High‐performance
binders
have
emerged
as
critical
component
in
addressing
this
challenge.
Although
they
represent
small
proportion
battery's
composition,
play
pivotal
role
enhancing
electrochemical
efficiency,
safety,
cost‐effectiveness
batteries.
advancement
rendered
traditional
inadequate,
prompting
development
functional
that
are
increasingly
being
refined
requirements.
This
article
began
by
outlining
requirements
within
electrodes,
examining
cutting‐edge
characterization
methodologies,
discussing
“structure‐function”
paradigm
underpins
binder
selection.
It
then
showcased
research
advancements
identifying
suitable
materials,
including
silicon
(Si),
phosphorus
(P),
tin
(Sn),
antimony
(Sb),
germanium
(Ge).
In
summary,
contemplated
future
direction
application
materials.
aim
is
facilitate
progression
high‐performance,
anodes,
thereby
accelerating
high‐energy‐density
lithium‐ion
sodium‐ion
