Energy & Fuels,
Journal Year:
2024,
Volume and Issue:
38(14), P. 12528 - 12545
Published: July 4, 2024
In
the
pursuit
of
advancements
within
realm
solid-state
lithium
metal
batteries,
considerable
attention
has
been
directed
toward
garnet-type
Li7La3Zr2O12
(LLZO)
material
owing
to
its
exceptional
stability,
elevated
ionic
conductivity
at
room
temperature,
compatibility
with
high
operating
voltages,
and
environmentally
friendly
low-cost
production
methodologies.
Despite
these
merits,
widespread
utilization
LLZO
in
conjunction
a
anode
is
significantly
impeded
by
emergence
interfacial
resistance
interface
dendrite
growth
issues.
When
challenges
are
addressed,
this
paper
comprehensively
examines
mechanistic
underpinnings
issues
arising
from
interaction
between
anode.
Furthermore,
it
surveys
latest
improvement
methodologies
employed
mitigate
concerns,
aiming
propel
advancement
battery
technology.
Chemical Reviews,
Journal Year:
2025,
Volume and Issue:
unknown
Published: Feb. 4, 2025
Solid-state
batteries
(SSBs)
could
offer
improved
energy
density
and
safety,
but
the
evolution
degradation
of
electrode
materials
interfaces
within
SSBs
are
distinct
from
conventional
with
liquid
electrolytes
represent
a
barrier
to
performance
improvement.
Over
past
decade,
variety
imaging,
scattering,
spectroscopic
characterization
methods
has
been
developed
or
used
for
characterizing
unique
aspects
in
SSBs.
These
efforts
have
yielded
new
understanding
behavior
lithium
metal
anodes,
alloy
composite
cathodes,
these
various
solid-state
(SSEs).
This
review
provides
comprehensive
overview
strategies
applied
SSBs,
it
presents
mechanistic
SSB
that
derived
methods.
knowledge
critical
advancing
technology
will
continue
guide
engineering
toward
practical
performance.
Next Energy,
Journal Year:
2024,
Volume and Issue:
3, P. 100115 - 100115
Published: March 23, 2024
Lithium-ion
batteries
(LIBs)
often
encounter
performance
decline
issues
in
cold
conditions
when
temperature
significantly
drops,
despite
being
widely
regarded
as
a
leading
battery
technology.
Functioning
typical
rocking-chair
battery,
lithium
ions
shuttle
through
the
"blood"
(the
electrolyte)
of
LIBs
between
graphite
anode
commonly-used
negative
electrode)
and
intercalation
compound
cathode
(positive
electrode),
where
ion
movement
tends
to
slow
down
with
decreasing
temperature.
Considering
relative
maturity
electrode
materials,
researchers
generally
pay
attention
electrolyte
corresponding
electrode/electrolyte
interphase
order
accelerate
transport.
In
light
significant
advancements,
we
herein
try
delineate
categorize
engineering
depict
what
next
can
be
done
build
better
suitable
for
cooler
temperatures
near
future.
Specifically,
advances
are
summarized
goal
improving
ionic
conductivity
bulk
electrolyte,
facilitating
desolvation
dynamics
at
interface,
accelerating
across
interfacial
film.
Furthermore,
viable
strategies
outlined
understand
design
principles
low-temperature
inspire
more
endeavors
overcome
critical
challenges
faced
by
extreme
conditions.
Advanced Materials,
Journal Year:
2024,
Volume and Issue:
unknown
Published: Nov. 3, 2024
Abstract
Bacterial
cellulose
(BC)
is
produced
via
the
fermentation
of
various
microorganisms.
It
has
an
interconnected
3D
porous
network
structure,
strong
water‐locking
ability,
high
mechanical
strength,
chemical
stability,
anti‐shrinkage
properties,
renewability,
biodegradability,
and
a
low
cost.
BC‐based
materials
their
derivatives
have
been
utilized
to
fabricate
advanced
functional
for
electrochemical
energy
storage
devices
flexible
electronics.
This
review
summarizes
recent
progress
in
development
BC‐related
devices.
The
origin,
components,
microstructure
BC
are
discussed,
followed
by
advantages
using
applications.
Then,
material
design
strategies
terms
solid
electrolytes,
binders,
separators,
as
well
BC‐derived
carbon
nanofibers
electroactive
discussed.
Finally,
short
conclusion
outlook
regarding
current
challenges
future
research
opportunities
related
next‐generation
suggestions
proposed.
Nature Communications,
Journal Year:
2025,
Volume and Issue:
16(1)
Published: Jan. 2, 2025
A
pressing
need
for
enhancing
lithium-ion
battery
(LIB)
performance
exists,
particularly
in
ensuring
reliable
operation
under
extreme
cold
conditions.
All-solid-state
batteries
(ASSBs)
offer
a
promising
solution
to
the
challenges
posed
by
conventional
LIBs
with
liquid
electrolytes
low-temperature
environments.
In
this
study,
leveraging
benefits
of
amorphous
solid-state
(SSEs)
xLi3N-TaCl5
(1
≤
3x
2),
we
develop
ASSBs
capable
functioning
effectively
The
designed
ASSBs,
employing
LiCoO2
positive
electrode
mass
loading
4.46
mg
cm‒2
and
Li-In
negative
electrode,
demonstrate
initial
discharge
capacities
183.19,
164.8
143.78
mAh
g‒1
18
mA
at
‒10,
‒30,
‒40
°C,
respectively,
exhibit
final
capacity
137.6
‒30
°C
100th
cycle.
Moreover,
an
51.94
‒60
cycling
over
200
h.
Lithium-ion
often
struggle
maintain
Here,
authors
solid
(xLi₃N-TaCl₅)
high
ionic
conductivities
design
all-solid-state
operating
hours.
Energy & Environmental Science,
Journal Year:
2025,
Volume and Issue:
unknown
Published: Jan. 1, 2025
The
activated
hopping
of
ultrasmall
nanoparticles,
in
conjunction
with
the
accelerated
segmental
motion
polymer,
establishes
a
dual-channel
Li
+
transport
pathway
that
significantly
enhances
conductivity
polymer
electrolyte.
Advanced Materials,
Journal Year:
2025,
Volume and Issue:
unknown
Published: April 8, 2025
Abstract
Sodium
solid‐state
batteries
(SSSBs)
are
poised
to
revolutionize
energy
storage
by
capitalizing
on
sodium's
exceptional
crustal
abundance
(2.36%
vs
0.0017%
for
lithium)
and
cost‐effectiveness,
addressing
critical
sustainability
challenges
of
lithium‐dependent
technologies.
Solid
electrolytes
(SEs)
with
high
ionic
conductivity
stability
have
gained
significant
attention.
The
compositional
structural
flexibility
perovskites
anti‐perovskites
make
them
competitive,
the
combination
advanced
computer
simulations
synthesis
techniques
can
achieve
stable
materials.
Importantly,
perovskite
anti‐perovskite
SEs
at
room
temperature
endow
enormous
potential
construction
SSSBs.
In
this
review,
research
progress
SSSBs
is
summarized,
different
optimization
strategies
improving
compared,
an
in‐depth
discussion
chemical
electrochemical
provided.
Specifically,
key
technical
indicators
reflecting
their
tolerance
future
application
been
summarized
discussed
first
time.
Among
these,
anti‐perovskites,
due
diversity
presence
more
ion
transport
channels,
become
commercial
SEs.
Finally,
development
directions
prospected.
Small,
Journal Year:
2024,
Volume and Issue:
unknown
Published: Nov. 26, 2024
Abstract
Developing
solid‐state
lithium
metal
batteries
with
wide
operating
temperature
range
is
important
in
future.
Polyethylene
oxide
(PEO)‐based
electrolytes
are
extensively
studied
for
merits
including
superior
flexibility
and
low
glass
transition
temperature.
However,
ideal
usage
temperatures
conventional
PEO‐based
between
60
65
°C,
unequable
degrades
their
electrochemical
performances
at
high
(≤25
°C
≥80
°C).
Herein,
modification
methods
of
PEO
low,
especially
wide‐temperature
applications
reviewed
based
on
detailed
analyses
mechanisms
involved
its
different
temperatures.
First,
shortcomings
solid
due
to
influence
pointed
out.
Second,
existing
strategies
summarized
detail
from
three
aspects
high,
temperatures,
application
derivatives
or
chain
segment
treatment
PEO,
addition
fillers,
other
such
as
reasonable
regulation
salts,
introduction
functional
layers
metal‐organic
frameworks
(MOFs)
covalent
organic
(COFs).
Finally,
a
summary
description
electrolyte
research
development
trends
provided.
The
review
aims
offer
some
guidance
the
creation
wider
working
ranges.
