Angewandte Chemie,
Год журнала:
2024,
Номер
unknown
Опубликована: Окт. 10, 2024
Abstract
Solid‐electrolyte
interphase
(SEI)
plays
a
decisive
role
in
building
reliable
Li
metal
batteries.
However,
the
scarcity
of
anions
Helmholtz
layer
(HL)
caused
by
electrostatic
repulsion
usually
leads
to
inferior
SEI
derived
from
solvents,
resulting
dendrites
and
‘dead’
Li.
Therefore,
regulating
distribution
electric
double
(EDL)
continuously
introducing
more
into
HL
tailor
anions‐derived
is
crucial
for
achieving
stable
plating/stripping.
Herein,
jointly
utilizing
controlled
defects
reduced
graphene
oxide
(rGO)
oriented
dipoles
ferroelectric
BaTiO
3
(BTO),
rGO‐BTO
composite
sustainedly
brings
TFSI
−
NO
anion‐defecient
HL,
promoting
favorable
decomposition
guiding
generation
robust
fast‐Li
+
‐transport
containing
inorganics
LiF
N
species.
Thus,
deposit
shows
smooth
dense
morphologies
without
dendrites,
leading
high
average
Coulombic
efficiency.
The
Li//Cu@rGO‐BTO
(10
mAh
cm
−2
plated
Li)
cell
exhibits
an
enhanced
plating/stripping
stability
(2700
h)
higher
rate
capability.
LiFePO
4
full
(N/P≈6.3)
using
displays
capacity
retention
(82.0
%
@
430
cycles).
This
work
provides
new
insight
on
construction
within
EDL.
Abstract
Composite
polymer
electrolytes
(CPEs),
produced
by
incorporating
inorganic
nanoparticles
(NPs)
into
matrices,
have
gained
significant
attention
as
promising
candidates
for
solid‐state
lithium
metal
batteries
(LMBs).
However,
the
aggregation
of
dense
fillers
results
in
nonuniform
CPEs,
thereby
impeding
LMB
performance.
Here,
we
fabricated
in‐situ
photo‐polymerized
CPEs
different
weight
ratios
(0–20
wt%)
Li
6.4
La
3
Zr
1.4
Ta
0.6
O
12
(LLZTO)
a
electrolyte
system
composed
poly(butyl
acrylate)‐based
elastomer
and
succinonitrile‐based
plastic
crystal
phases.
The
rapid
photo‐polymerization
process
(~5
min)
enabled
homogeneous
dispersion
LLZTO
within
CPE
matrix
at
10
wt%
(L10),
resulting
high
ionic
conductivity
(1.02
mS
cm
−1
25°C)
mechanical
elasticity
(elongation
break
≈
1250%)
compared
to
those
without
(L0).
As
result,
L10‐based
with
LiNi
0.8
Co
0.1
Mn
2
cathode
exhibited
capacity
166.7
mAh
g
after
200
cycles
0.5C,
significantly
higher
than
L0
(74.0
)
L20
(104.8
).
In
comparison,
thermal
polymerized
NPs
showed
due
slow
polymerization
kinetics
(~2
h),
inferior
cycling
performance
L10.
This
work
highlights
importance
homogenous
achieve
robustness
suitable
stable
operation
LMBs.
image
Materials Chemistry Frontiers,
Год журнала:
2024,
Номер
8(21), С. 3569 - 3576
Опубликована: Янв. 1, 2024
A
new
composite
electrolyte,
combined
with
rigid
fillers
and
high
dielectric
polymers,
promotes
the
dissociation
of
lithium
salts
construction
multiple
Li
+
paths,
improving
metal
batteries
performances
at
room
low
temperatures.
Angewandte Chemie International Edition,
Год журнала:
2024,
Номер
unknown
Опубликована: Окт. 10, 2024
Abstract
Solid‐electrolyte
interphase
(SEI)
plays
a
decisive
role
in
building
reliable
Li
metal
batteries.
However,
the
scarcity
of
anions
Helmholtz
layer
(HL)
caused
by
electrostatic
repulsion
usually
leads
to
inferior
SEI
derived
from
solvents,
resulting
dendrites
and
‘dead’
Li.
Therefore,
regulating
distribution
electric
double
(EDL)
continuously
introducing
more
into
HL
tailor
anions‐derived
is
crucial
for
achieving
stable
plating/stripping.
Herein,
jointly
utilizing
controlled
defects
reduced
graphene
oxide
(rGO)
oriented
dipoles
ferroelectric
BaTiO
3
(BTO),
rGO‐BTO
composite
sustainedly
brings
TFSI
−
NO
anion‐defecient
HL,
promoting
favorable
decomposition
guiding
generation
robust
fast‐Li
+
‐transport
containing
inorganics
LiF
N
species.
Thus,
deposit
shows
smooth
dense
morphologies
without
dendrites,
leading
high
average
Coulombic
efficiency.
The
Li//Cu@rGO‐BTO
(10
mAh
cm
−2
plated
Li)
cell
exhibits
an
enhanced
plating/stripping
stability
(2700
h)
higher
rate
capability.
LiFePO
4
full
(N/P≈6.3)
using
displays
capacity
retention
(82.0
%
@
430
cycles).
This
work
provides
new
insight
on
construction
within
EDL.
Angewandte Chemie,
Год журнала:
2024,
Номер
unknown
Опубликована: Окт. 10, 2024
Abstract
Solid‐electrolyte
interphase
(SEI)
plays
a
decisive
role
in
building
reliable
Li
metal
batteries.
However,
the
scarcity
of
anions
Helmholtz
layer
(HL)
caused
by
electrostatic
repulsion
usually
leads
to
inferior
SEI
derived
from
solvents,
resulting
dendrites
and
‘dead’
Li.
Therefore,
regulating
distribution
electric
double
(EDL)
continuously
introducing
more
into
HL
tailor
anions‐derived
is
crucial
for
achieving
stable
plating/stripping.
Herein,
jointly
utilizing
controlled
defects
reduced
graphene
oxide
(rGO)
oriented
dipoles
ferroelectric
BaTiO
3
(BTO),
rGO‐BTO
composite
sustainedly
brings
TFSI
−
NO
anion‐defecient
HL,
promoting
favorable
decomposition
guiding
generation
robust
fast‐Li
+
‐transport
containing
inorganics
LiF
N
species.
Thus,
deposit
shows
smooth
dense
morphologies
without
dendrites,
leading
high
average
Coulombic
efficiency.
The
Li//Cu@rGO‐BTO
(10
mAh
cm
−2
plated
Li)
cell
exhibits
an
enhanced
plating/stripping
stability
(2700
h)
higher
rate
capability.
LiFePO
4
full
(N/P≈6.3)
using
displays
capacity
retention
(82.0
%
@
430
cycles).
This
work
provides
new
insight
on
construction
within
EDL.
