Batteries,
Год журнала:
2024,
Номер
10(7), С. 255 - 255
Опубликована: Июль 17, 2024
Solid-state
batteries
(SSBs)
have
emerged
as
a
promising
alternative
to
conventional
lithium-ion
batteries,
with
notable
advantages
in
safety,
energy
density,
and
longevity,
yet
the
environmental
implications
of
their
life
cycle,
from
manufacturing
disposal,
remain
critical
concern.
This
review
examines
impacts
associated
production,
use,
end-of-life
management
SSBs,
starting
extraction
processing
raw
materials,
highlights
significant
natural
resource
consumption,
emissions.
A
comparative
analysis
traditional
battery
underscores
hazards
novel
materials
specific
SSBs.
The
also
assesses
operational
impact
SSBs
by
evaluating
efficiency
carbon
footprint
comparison
followed
an
exploration
challenges,
including
disposal
risks,
regulatory
frameworks,
shortcomings
existing
waste
practices.
focus
is
placed
on
recycling
reuse
strategies,
reviewing
current
methodologies
like
mechanical,
pyrometallurgical,
hydrometallurgical
processes,
along
emerging
technologies
that
aim
overcome
barriers,
while
analyzing
economic
technological
challenges
these
processes.
Additionally,
real-world
case
studies
are
presented,
serving
benchmarks
for
best
practices
highlighting
lessons
learned
field.
In
conclusion,
paper
identifies
research
gaps
future
directions
reducing
underscoring
need
interdisciplinary
collaboration
advance
sustainable
SSB
contribute
balancing
advancements
stewardship,
thereby
supporting
transition
more
future.
Advanced Materials,
Год журнала:
2022,
Номер
35(19)
Опубликована: Ноя. 18, 2022
Abstract
All‐solid‐state
batteries
have
piqued
global
research
interest
because
of
their
unprecedented
safety
and
high
energy
density.
Significant
advances
been
made
in
achieving
room‐temperature
ionic
conductivity
good
air
stability
solid‐state
electrolytes
(SSEs),
mitigating
the
challenges
at
electrode–electrolyte
interface,
developing
feasible
manufacturing
processes.
Along
with
fundamental
study,
all‐solid‐state
pouch
cells
using
inorganic
SSEs
widely
demonstrated,
revealing
immense
potential
for
industrialization.
This
review
provides
an
overview
cells,
focusing
on
ultrathin
SSE
membranes,
sheet‐type
thick
electrodes,
bipolar
stacking.
Moreover,
several
critical
parameters
directly
influencing
density
Li‐ion
lithium–sulfur
are
outlined.
Finally,
perspectives
provided
specific
metrics
to
meet
certain
targets
specified.
looks
facilitate
development
excellent
safety.
Advanced Materials,
Год журнала:
2022,
Номер
35(50)
Опубликована: Авг. 19, 2022
Abstract
All‐solid‐state
lithium
batteries
(ASSLBs)
employing
sulfide
solid
electrolytes
(SEs)
promise
sustainable
energy
storage
systems
with
energy‐dense
integration
and
critical
intrinsic
safety,
yet
they
still
require
cost‐effective
manufacturing
the
of
thin
membrane‐based
SE
separators
into
large‐format
cells
to
achieve
scalable
deployment.
This
review,
based
on
an
overview
materials,
is
expounded
why
implementing
a
separator
priority
for
mass
production
ASSLBs
criteria
capturing
high‐quality
membrane
are
identified.
Moreover,
from
aspects
material
availability,
processing,
cell
integration,
major
challenges
associated
strategies
described
meet
these
throughout
whole
chain
provide
realistic
assessment
current
status
membranes.
Finally,
future
directions
prospects
manufacturable
membranes
presented.
Chemical Society Reviews,
Год журнала:
2024,
Номер
53(10), С. 5264 - 5290
Опубликована: Янв. 1, 2024
The
energy
storage
and
vehicle
industries
are
heavily
investing
in
advancing
all-solid-state
batteries
to
overcome
critical
limitations
existing
liquid
electrolyte-based
lithium-ion
batteries,
specifically
focusing
on
mitigating
fire
hazards
improving
density.
All-solid-state
lithium-sulfur
(ASSLSBs),
featuring
earth-abundant
sulfur
cathodes,
high-capacity
metallic
lithium
anodes,
non-flammable
solid
electrolytes,
hold
significant
promise.
Despite
these
appealing
advantages,
persistent
challenges
like
sluggish
redox
kinetics,
metal
failure,
electrolyte
degradation,
manufacturing
complexities
hinder
their
practical
use.
To
facilitate
the
transition
of
technologies
an
industrial
scale,
bridging
gap
between
fundamental
scientific
research
applied
R&D
activities
is
crucial.
Our
review
will
address
inherent
cell
chemistries
within
ASSLSBs,
explore
advanced
characterization
techniques,
delve
into
innovative
structure
designs.
Furthermore,
we
provide
overview
recent
trends
investment
from
both
academia
industry.
Building
understandings
progress
that
has
been
made
thus
far,
our
objective
motivate
battery
community
advance
ASSLSBs
a
direction
propel
industrialized
process.
Advanced Materials,
Год журнала:
2023,
Номер
35(51)
Опубликована: Май 16, 2023
Lithium
(Li)-based
batteries
are
gradually
evolving
from
the
liquid
to
solid
state
in
terms
of
safety
and
energy
density,
where
all
solid-state
Li-metal
(ASSLMBs)
considered
most
promising
candidates.
This
is
demonstrated
by
Bluecar
electric
vehicle
produced
Bolloré
Group,
which
utilized
car-sharing
services
several
cities
worldwide.
Despite
impressive
progress
development
ASSLMBs,
their
avenues
for
recycling
them
remain
underexplored,
combined
with
current
explosion
spent
Li-ion
batteries,
they
should
attract
widespread
interest
academia
industry.
Here,
potential
challenges
ASSLMBs
as
compared
analyzed
prospects
summarized
analyzed.
Drawing
on
lessons
learned
battery
recycling,
it
important
design
sustainable
technologies
before
gain
market
adoption.
A
battery-recycling-oriented
also
highlighted
promote
rate
maximize
profitability.
Finally,
future
research
directions,
challenges,
outlined
provide
strategies
achieving
ASSLMBs.
Batteries,
Год журнала:
2024,
Номер
10(1), С. 29 - 29
Опубликована: Янв. 17, 2024
The
primary
goal
of
this
review
is
to
provide
a
comprehensive
overview
the
state-of-the-art
in
solid-state
batteries
(SSBs),
with
focus
on
recent
advancements
solid
electrolytes
and
anodes.
paper
begins
background
evolution
from
liquid
electrolyte
lithium-ion
advanced
SSBs,
highlighting
their
enhanced
safety
energy
density.
It
addresses
increasing
demand
for
efficient,
safe
storage
applications
like
electric
vehicles
portable
electronics.
A
major
part
analyzes
electrolytes,
key
SSB
technology.
classifies
as
polymer-based,
oxide-based,
sulfide-based,
discussing
distinct
properties
application
suitability.
also
covers
anode
materials
exploring
lithium
metal,
silicon,
intermetallic
compounds,
focusing
capacity,
durability,
compatibility
electrolytes.
challenges
integrating
these
materials,
interface
stability
dendrite
growth.
This
includes
discussion
latest
analytical
techniques,
experimental
studies,
computational
models
understand
improve
anode–solid
interface.
These
are
crucial
tackling
interfacial
resistance
ensuring
SSBs’
long-term
efficiency.
Concluding,
suggests
future
research
development
directions,
potential
revolutionizing
technologies.
serves
vital
resource
academics,
researchers,
industry
professionals
battery
technology
development.
offers
detailed
technologies
shaping
future,
providing
insights
into
current
solutions
rapidly
evolving
field.
ACS Energy Letters,
Год журнала:
2023,
Номер
8(7), С. 3196 - 3203
Опубликована: Июнь 29, 2023
Achieving
high
areal
capacity
and
rate
performance
in
solid-state
battery
electrodes
is
challenging
due
to
sluggish
charge
carrier
transport
through
thick
all-solid
composite
electrodes,
as
the
strongly
relies
on
microstructure
porosity
of
compressed
composite.
Introducing
a
high-capacity
material
like
silicon
for
such
purpose
would
require
fast
ionic
electronic
throughout
electrode.
In
this
work,
by
designing
electrode
containing
Si
nanoparticles,
superionic
solid
electrolyte
(SE),
carbon
additive,
possibility
achieving
capacities
over
10
mAh·cm–2
4
at
current
densities
1.6
mA·cm–2
8
mA·cm–2,
respectively,
room
temperature
demonstrated.
Using
DC
polarization
measurements,
impedance
spectroscopy,
microscopic
analyses,
modeling,
we
establish
that
route
achieve
high-performance
anode
composites
modulation
attaining
silicon/solid
interface
contacts,
particle
size
compatibility
components,
their
well-distributed
compact
packing
