Nano Letters,
Год журнала:
2024,
Номер
24(26), С. 8055 - 8062
Опубликована: Июнь 21, 2024
The
unstable
solid
electrolyte
interface
(SEI)
formed
by
uncontrollable
degradation,
which
leads
to
dendrite
growth
and
Coulombic
efficiency
decay,
hinders
the
development
of
Li
metal
anodes.
A
controllable
desolvation
process
is
essential
for
formation
stable
SEI
improved
lithium
deposition
behavior.
Here,
we
show
a
functional
artificial
protective
layer
comprised
chondroitin
sulfate-reduced
graphene
oxide
(CrG),
on
polar
groups
are
distributed
effectively
reduce
energy
barrier
The
lithium
(Li)
metal
anode
(LMA)
is
susceptible
to
failure
due
the
growth
of
Li
dendrites
caused
by
an
unsatisfied
solid
electrolyte
interface
(SEI).
With
this
regard,
design
artificial
SEIs
with
improved
physicochemical
and
mechanical
properties
has
been
demonstrated
be
important
stabilize
LMAs.
This
review
comprehensively
summarizes
current
efficient
strategies
key
progresses
in
surface
engineering
for
constructing
protective
layers
serve
as
SEIs,
including
pretreating
LMAs
reagents
situated
different
primary
states
matter
(solid,
liquid,
gas)
or
using
some
peculiar
pathways
(plasma,
example).
fundamental
characterization
tools
studying
on
are
also
briefly
introduced.
Last,
strategic
guidance
deliberate
provided,
challenges,
opportunities,
possible
future
directions
these
development
practical
applications
discussed.
Advanced Materials,
Год журнала:
2023,
Номер
35(38)
Опубликована: Июнь 3, 2023
Ultrathin
and
super-toughness
gel
polymer
electrolytes
(GPEs)
are
the
key
enabling
technology
for
durable,
safe,
high-energy
density
solid-state
lithium
metal
batteries
(SSLMBs)
but
extremely
challenging.
However,
GPEs
with
limited
uniformity
continuity
exhibit
an
uneven
Li+
flux
distribution,
leading
to
nonuniform
deposition.
Herein,
a
fiber
patterning
strategy
developing
engineering
ultrathin
(16
µm)
fibrous
high
ionic
conductivity
(≈0.4
mS
cm-1
)
superior
mechanical
toughness
(≈613%)
durable
safe
SSLMBs
is
proposed.
The
special
patterned
structure
provides
fast
transport
channels
tailoring
solvation
of
traditional
LiPF6
-based
carbonate
electrolyte,
rapid
transfer
kinetics
uniform
flux,
boosting
stability
against
Li
anodes,
thus
realizing
ultralong
plating/stripping
in
symmetrical
cell
over
3000
h
at
1.0
mA
cm-2
,
mAh
.
Moreover,
LiFePO4
loading
10.58
mg
deliver
stable
cycling
life
1570
cycles
C
92.5%
capacity
retention
excellent
rate
129.8
g-1
5.0
cut-off
voltage
4.2
V
(100%
depth-of-discharge).
Patterned
systems
powerful
strategies
producing
SSLMBs.
Angewandte Chemie International Edition,
Год журнала:
2023,
Номер
62(39)
Опубликована: Авг. 2, 2023
Lithium
fluoride
(LiF)
at
the
solid
electrolyte
interface
(SEI)
contributes
to
stable
operation
of
polymer-based
solid-state
lithium
metal
batteries.
Currently,
most
methods
for
constructing
SEI
are
based
on
design
polar
groups
fillers.
However,
mechanism
behind
how
steric
hindrance
fillers
impacts
LiF
formation
remains
unclear.
This
study
synthesizes
three
kinds
porous
polyacetal
amides
(PAN-X,
X=NH2
,
NH-CH3
N-(CH3
)2
)
with
varying
hindrances
by
regulating
number
methyl
substitutions
nitrogen
atoms
reaction
monomer,
which
incorporated
into
polymer
composite
electrolytes,
investigate
regulation
content
in
SEI.
The
results
show
that
bis(trifluoromethanesulfonyl)imide
(TFSI-
will
compete
charge
without
effect,
while
excessive
hinders
interaction
between
TFSI-
and
groups,
reducing
acquisition.
Only
when
one
hydrogen
atom
amino
group
is
replaced
a
group,
from
prevents
capturing
direction,
thereby
facilitating
transfer
separate
promoting
maximum
formation.
work
provides
novel
perspective
LiF-rich
Angewandte Chemie International Edition,
Год журнала:
2023,
Номер
62(44)
Опубликована: Сен. 15, 2023
Coupled
electron/ion
transport
is
a
decisive
feature
of
Li
plating/stripping,
wherein
the
compatibility
rates
determines
morphology
deposited
Li.
Local
Li+
hotspots
form
due
to
inhomogeneous
interfacial
charge
transfer
and
lead
uncontrolled
deposition,
which
decreases
utilization
rate
safety
metal
anodes.
Herein,
we
report
method
obtain
dendrite-free
anodes
by
driving
electron
pumping
accumulating
boosting
ion
diffusion
tuning
work
function
carbon
host
using
cobalt-containing
catalysts.
The
results
reveal
that
increasing
provides
an
deviation
from
C
Co,
electron-rich
Co
shows
favorable
binding
.
catalysts
boost
on
fiber
scaffolds
without
local
aggregation
reducing
migration
barrier.
as-obtained
anode
exhibits
Coulombic
efficiency
99.0
%,
cycle
life
over
2000
h,
50
capacity
retention
83.4
%
after
130
cycles
in
pouch
cells
at
negative/positive
ratio
2.5.
These
findings
provide
novel
strategy
stabilize
regulating
materials
electrocatalysts.
Nature Communications,
Год журнала:
2024,
Номер
15(1)
Опубликована: Март 13, 2024
Applying
high
stack
pressure
(often
up
to
tens
of
megapascals)
solid-state
Li-ion
batteries
is
primarily
done
address
the
issues
internal
voids
formation
and
subsequent
transport
blockage
within
solid
electrode
due
volume
changes.
Whereas,
redundant
pressurizing
devices
lower
energy
density
raise
cost.
Herein,
a
mechanical
optimization
strategy
involving
elastic
electrolyte
proposed
for
SSBs
operating
without
external
pressurizing,
but
relying
solely
on
built-in
cells.
We
combine
soft-rigid
dual
monomer
copolymer
with
deep
eutectic
mixture
design
an
electrolyte,
which
exhibits
not
only
stretchability
deformation
recovery
capability
also
room-temperature
conductivity
2×10
Accounts of Chemical Research,
Год журнала:
2024,
Номер
57(6), С. 992 - 1006
Опубликована: Фев. 28, 2024
ConspectusMechanically
interlocked
polymers
(MIPs)
such
as
polyrotaxanes
and
polycatenanes
are
polymer
architectures
that
incorporate
mechanical
bonds,
which
represent
a
compelling
frontier
in
science.
MIPs
with
cross-linked
structures
known
mechanically
networks
(MINs)
widely
utilized
materials
Leveraging
the
motion
of
MINs
hold
potential
for
achieving
combination
robustness
dynamicity.
Currently,
reported
predominantly
consist
discrete
bonds
cross-linking
points,
exemplified
by
well-known
slide-ring
rotaxane/catenane
polymers.
The
these
points
facilitates
redistribution
tension
throughout
network,
effectively
preventing
stress
concentration
thereby
enhancing
material
toughness.
In
instances,
impact
can
be
likened
to
adage
"small
things
make
big
difference",
whereby
limited
number
substantially
elevate
performance
conventional
addition
there
is
another
type
MIN
their
principal
parts
chains
composed
dense
bonds.
Within
MINs,
generally
serve
repeating
units,
unique
properties
stem
from
integrating
amplifying
function
large
amount
Consequently,
tend
reflect
intrinsic
polymers,
making
exploration
critical
comprehensive
understanding
MIPs.
Nevertheless,
investigations
into
featuring
remain
relatively
scarce.This
Account
presents
overview
our
investigation
insights
First,
we
delve
synthetic
strategies
employed
prepare
while
critically
evaluating
advantages
limitations.
Through
meticulous
control
core
interlocking
step,
three
distinct
have
emerged:
followed
polymerization,
supramolecular
polymerization
interlocking,
dynamic
interlocking.
Furthermore,
underscore
structure–property
relationships
macroscopic
originate
countless
microscopic
motions
phenomenon
define
an
integration
amplification
mechanism.
Our
has
revealed
detailed
characteristics
bulk
materials,
encompassing
quantification
activation
energy,
discrimination
varying
distances,
elucidation
recovery
process.
Additionally,
elucidated
influence
on
respective
materials.
Moreover,
explored
applications
leveraging
exceptional
These
include
toughness
engineering
adaptive
multifunctional
aerogels,
mitigating
Li
protrusion
interfacial
layers
lithium-ion
batteries.
Finally,
offer
personal
perspectives
promises,
opportunities,
key
challenges
future
development
underscoring
transformative
advancements
this
burgeoning
field.
Solid
polymer
electrolytes
suffer
from
the
polymer-dominated
Li
+
solvation
structure,
causing
unstable
electrolyte/electrode
interphases
and
deteriorated
battery
performance.
Here,
we
design
a
class
of
selectively
fluorinated
aromatic
lithium
salts
(SFALS)
as
single
conducting
to
regulate
structure
interfacial
chemistry
for
all-solid-state
metal
batteries.
By
tuning
anionic
-polyether
coupling
is
weakened,
-anion
coordination
enhanced.
The
hydrogen
bonding
between
SFALS
matrix
induces
special
“triad”-type
which
improves
electrolyte
homogeneity
mechanical
strength,
promotes
formation
an
ultrathin
robust
2
O-rich
solid
interphase.
Therefore,
stable
cycling
more
than
1650
cycles
(Coulombic
efficiency,
99.8%)
LiFePO
4
/Li
half
cells
580
(97.4%
capacity
retention)
full
achieved.
This
molecular
engineering
strategy
could
inspire
further
advancements
functional
practical
application
Advanced Energy Materials,
Год журнала:
2023,
Номер
13(43)
Опубликована: Окт. 3, 2023
Abstract
Lithium
nitrate
is
an
attractive
lithium
additive
in
the
construction
of
high‐performance
metal
anodes
with
a
Li
3
N‐rich
solid
electrolyte
interphase
(SEI)
layer.
However,
eight‐electron
transfer
process
induces
high
energy
barriers
between
LiNO
and
N.
Herein,
inner
Helmholtz
plane
tuned
on
deposition
host
to
attain
sluggish/rapid
decomposition
kinetics,
resulting
different
intermediate
content
distributions
species
SEI.
Notably,
oxynitride
(LiNO)
identified
as
intermediate,
experimental
simulation
results
confirm
its
role
obstructing
decomposition.
Moreover,
reveal
that
dipole–dipole
interaction
polar
V≡N
bond
can
change
ionic/covalent
character
N═O
bonds,
considerably
facilitating
cleavage,
promoting
reduction
achieve
Consequently,
when
contains
0.37
m
,
dendrite,
dead
formation
are
suppressed
effectively
VN
system,
average
Coulombic
efficiency
99.7%
over
1000
cycles
(1
mA
cm
−2
1
mAh
)
be
attained.
These
promote
nitride
oxidation
break
pave
way
for
fabricating
batteries.
