Angewandte Chemie International Edition,
Journal Year:
2024,
Volume and Issue:
unknown
Published: July 26, 2024
Deep
eutectic
electrolytes
(DEEs)
are
regarded
as
one
of
the
next-generation
to
promote
development
lithium
metal
batteries
(LMBs)
due
their
unparalleled
advantages
compared
both
liquid
and
solid
electrolytes.
However,
its
application
in
LMBs
is
limited
by
electrode
interface
compatibility.
Here,
we
introduce
a
novel
dimethylmalononitrile
(DMMN)-based
DEE
induced
N
coordination
dissociate
LiTFSI.
We
confirmed
that
DMMN
molecule
can
dissociation
LiTFSI
interaction
between
atom
Li
Angewandte Chemie International Edition,
Journal Year:
2024,
Volume and Issue:
63(18)
Published: March 12, 2024
Abstract
Poly(vinylidene
fluoride)
(PVDF)‐based
polymer
electro‐lytes
are
attracting
increasing
attention
for
high‐voltage
solid‐state
lithium
metal
batteries
because
of
their
high
room
temperature
ionic
conductivity,
adequate
mechanical
strength
and
good
thermal
stability.
However,
the
presence
highly
reactive
residual
solvents,
such
as
N,
N‐dimethylformamide
(DMF),
severely
jeopardizes
long‐term
cycling
Herein,
we
propose
a
solvation‐tailoring
strategy
to
confine
solvent
molecules
by
introducing
low‐cost
3
Å
zeolite
molecular
sieves
fillers.
The
strong
interaction
between
DMF
sieve
weakens
ability
participate
in
solvation
Li
+
,
leading
more
anions
being
involved
solvation.
Benefiting
from
tailored
anion‐rich
coordination
environment,
interfacial
side
reactions
with
anode
NCM811
cathode
effectively
suppressed.
As
result,
Li||Li
symmetrical
cells
demonstrates
ultra‐stable
over
5100
h
at
0.1
mA
cm
−2
Li||NCM811
full
achieve
excellent
stability
than
1130
250
cycles
under
charging
cut‐off
voltages
4.3
V
4.5
V,
respectively.
Our
work
is
an
innovative
exploration
address
negative
effects
PVDF‐based
electrolytes
highlights
importance
modulating
structures
electrolytes.
Angewandte Chemie International Edition,
Journal Year:
2024,
Volume and Issue:
63(17)
Published: March 5, 2024
Abstract
Acting
as
a
passive
protective
layer,
solid‐electrolyte
interphase
(SEI)
plays
crucial
role
in
maintaining
the
stability
of
Li‐metal
anode.
Derived
from
reductive
decomposition
electrolytes
(e.g.,
anion
and
solvent),
SEI
construction
presents
an
interfacial
process
accompanied
by
dynamic
de‐solvation
during
plating.
However,
typical
electrolyte
engineering
related
modification
strategies
always
ignore
evolution
configuration
at
Li/electrolyte
interface,
which
essentially
determines
architecture.
Herein,
employing
advanced
electrochemical
situ
FT‐IR
MRI
technologies,
we
directly
visualize
variations
solvation
environments
involving
Li
+
‐solvent/anion.
Remarkably,
weakened
‐solvent
interaction
anion‐lean
have
been
synchronously
revealed,
is
difficult
for
fabrication
anion‐derived
layer.
Moreover,
simple
regulation
strategy,
pulse
protocol
was
introduced
to
effectively
restore
concentration,
resulting
enhanced
LiF‐rich
layer
improved
plating/stripping
reversibility.
Nature Communications,
Journal Year:
2024,
Volume and Issue:
15(1)
Published: Oct. 23, 2024
Polyethylene
oxide
(PEO)
based
electrolytes
critically
govern
the
security
and
energy
density
of
solid-state
batteries,
but
typically
suffer
from
poor
oxidation
resistance
at
high
voltages,
which
limits
batteries.
Here,
we
report
a
Lewis-acid
coordinated
strategy
to
significantly
improve
cyclic
stability
4.8
V-class
PEO-based
battery.
The
introduced
Mg
Advanced Functional Materials,
Journal Year:
2024,
Volume and Issue:
34(19)
Published: Jan. 9, 2024
Abstract
Manganese‐based
layered
oxide
cathodes,
particularly
K
x
MnO
2
(KMO),
have
shown
great
potential
in
potassium‐ion
batteries
(PIBs)
due
to
their
low
cost,
high
theoretical
capacities,
and
excellent
thermal
stability.
However,
Jahn‐Teller
distortion,
manganese
dissolution,
interface
instability
of
electrode/electrolyte
lead
structural
performance
decay.
Here,
lithium
difluoro(oxalate)
borate
(LiDFOB)
is
introduced
as
an
electrolyte
additive
improve
the
electrochemical
P3‐type
KMO.
LiDFOB
creates
a
uniform,
thin,
robust
cathode‐electrolyte
interphase
layer
on
cathode
surface,
enhancing
reaction
kinetics,
preventing
stabilizing
structure.
The
P3‐KMO
with
basic
exhibits
significantly
improved
performance,
such
remarkable
Coulombic
efficiency
≈99.5%
capacity
retention
78.6%
after
300
cycles
at
100
mA
g
−1
.
Moreover,
full
cell
P3‐KMO||soft
carbon
demonstrates
satisfactory
specific
energy
density.
This
study
emphasizes
importance
chemistry
for
PIBs.
Nano-Micro Letters,
Journal Year:
2024,
Volume and Issue:
17(1)
Published: Sept. 20, 2024
To
address
the
limitations
of
contemporary
lithium-ion
batteries,
particularly
their
low
energy
density
and
safety
concerns,
all-solid-state
lithium
batteries
equipped
with
solid-state
electrolytes
have
been
identified
as
an
up-and-coming
alternative.
Among
various
SEs,
organic-inorganic
composite
solid
(OICSEs)
that
combine
advantages
both
polymer
inorganic
materials
demonstrate
promising
potential
for
large-scale
applications.
However,
OICSEs
still
face
many
challenges
in
practical
applications,
such
ionic
conductivity
poor
interfacial
stability,
which
severely
limit
This
review
provides
a
comprehensive
overview
recent
research
advancements
OICSEs.
Specifically,
influence
fillers
on
main
functional
parameters
OICSEs,
including
conductivity,
Li
ACS Nano,
Journal Year:
2025,
Volume and Issue:
unknown
Published: Jan. 10, 2025
Solid
polymer
electrolytes
(SPEs)
are
promising
candidates
for
lithium
metal
batteries
(LMBs)
owing
to
their
safety
features
and
compatibility
with
anodes.
However,
the
inferior
ionic
conductivity
electrochemical
stability
of
SPEs
hinder
application
in
high-voltage
solid-state
LMBs
(HVSSLMBs).
Here,
a
strategy
is
proposed
develop
dual-anion-rich
solvation
structure
by
implementing
ferroelectric
barium
titanate
(BTO)
nanoparticles
(NPs)
dual
salts
into
poly(vinylidene
fluoride)
(PVDF)-based
HVSSLMBs.
The
BTO
NPs
regulate
spatial
PVDF
segments,
enhancing
local
built-in
electric
field
SPEs,
which,
turn,
facilitates
dissolution
dissociation
salts.
This
contributes
an
enhanced
steric
effect,
which
significantly
improves
Li+
transport
kinetics
stability.
designed
PVDF-based
SPE
achieves
high
4.1
×
10–4
S
cm–1
transference
number
0.70
at
25
°C.
Li//Li
symmetric
cells
deliver
excellent
critical
current
density
2.4
mA
cm–2
maintain
stable
Li
plating/stripping
process
over
5000
h.
After
1000
cycles
2C,
LiFePO4//Li
achieve
discharge
capacity
108.3
mAh
g–1.
Furthermore,
LiNi0.8Co0.1Mn0.1O2
(NCM811)//Li
present
retention
after
300
1C
cutoff
voltage
4.4
V.
NCM811/Graphite
pouch
exhibit
cycling
performance.
work
illustrates
that
synergistic
integration
functional
multiple
holds
significant
potential
development
SPEs.
Nano-Micro Letters,
Journal Year:
2025,
Volume and Issue:
17(1)
Published: March 17, 2025
Abstract
Composite
solid
electrolytes
(CSEs)
are
promising
for
solid-state
Li
metal
batteries
but
suffer
from
inferior
room-temperature
ionic
conductivity
due
to
sluggish
ion
transport
and
high
cost
expensive
active
ceramic
fillers.
Here,
a
host–guest
inversion
engineering
strategy
is
proposed
develop
superionic
CSEs
using
cost-effective
SiO
2
nanoparticles
as
passive
hosts
poly(vinylidene
fluoride-hexafluoropropylene)
(PVH)
microspheres
polymer
guests,
forming
an
unprecedented
“polymer
guest-in-ceramic
host”
(i.e.,
PVH-in-SiO
)
architecture
differing
the
traditional
“ceramic
guest-in-polymer
host”.
The
exhibits
excellent
Li-salt
dissociation,
achieving
high-concentration
free
+
.
Owing
low
diffusion
energy
barriers
coefficient,
thermodynamically
kinetically
favorable
migrate
at
/PVH
interfaces.
Consequently,
delivers
exceptional
of
1.32
×
10
−3
S
cm
−1
25
°C
(vs
typically
−5
–10
−4
high-cost
ceramics),
achieved
under
ultralow
residual
solvent
content
2.9
wt%
8–15
in
other
CSEs).
Additionally,
electrochemically
stable
with
anode
various
cathodes.
Therefore,
demonstrates
high-rate
cyclability
LiFePO
4
|Li
full
cells
(92.9%
capacity-retention
3C
after
300
cycles
°C)
outstanding
stability
high-mass-loading
(9.2
mg
high-voltage
NCM622
(147.1
mAh
g
).
Furthermore,
we
verify
versatility
by
fabricating
Na-ion
K-ion-based
similarly
promotions
conductivity.
Our
offers
simple,
low-cost
approach
large-scale
application
beyond.
Advanced Functional Materials,
Journal Year:
2024,
Volume and Issue:
34(36)
Published: March 19, 2024
Abstract
The
practical
application
of
all‐solid‐state
lithium
metal
batteries
(ASSLMBs)
is
limited
by
(Li)
anode
instability
including
Li
dendrite
formation
and
deteriorating
interface
with
electrolytes.
Here,
a
functional
additive,
isosorbide
mononitrate
(ISMN)
non‐resonant
structure
(O
2
−N−O−)
reported,
which
improves
its
reactivity
utilized
to
build
stable
N‐rich
solid
electrolyte
interface,
effectively
alleviating
side
reactions
for
poly(vinylidene
fluoride)
(PVDF)‐lithium
bis(trifluoromethane
sulfonyl)
imide
(LiTFSI)‐based
(PLE‐ISMN).
In
addition,
the
ion‐dipole
interaction
between
ISMN
ions
facilitates
dissociation
LiTFSI
form
carrier
ions,
improving
ionic
conductivity
(4.4
×
10
−4
S
cm
−1
)
transference
number
(0.50)
PLE‐ISMN.
Consequently,
Li/Li
symmetric
cell
delivers
high
critical
current
density
2.0
mA
−2
stripping/plating
cycling
over
5000
h
capacity
1.0
mAh
.
Moreover,
Li|LiFePO
4
an
excellent
initial
discharge
154.0
g
outstanding
retention
88.9%
after
500
cycles
at
0.5
C.
Li|LiNi
0.8
Co
0.1
Mn
O
also
exhibits
good
performance
4.4
V
1
