Crystal Growth & Design,
Год журнала:
2024,
Номер
24(17), С. 6911 - 6930
Опубликована: Авг. 19, 2024
When
Olga
Kennard
founded
the
Cambridge
Crystallographic
Data
Centre
in
1965,
Structural
Database
was
a
pioneering
attempt
to
collect
scientific
data
standard
format.
Since
then,
it
has
evolved
into
an
indispensable
resource
contemporary
molecular
materials
science,
with
over
1.25
million
structures
and
comprehensive
software
tools
for
searching,
visualizing
analyzing
data.
In
this
perspective,
we
discuss
use
of
CSD
CCDC
address
multiscale
challenge
predictive
design.
We
provide
overview
core
capabilities
demonstrate
their
application
range
design
problems
recent
case
studies
drawn
from
topical
research
areas,
focusing
particular
on
mining
machine
learning
techniques.
also
identify
several
challenges
that
can
be
addressed
existing
or
through
new
varying
levels
development
effort.
Abstract
Microfluidic
technology
has
exhibited
remarkable
potential
and
significance
in
the
precise
preparation
of
multifunctional
nanomaterials.
Thanks
to
its
small
reaction
volume
superior
hydrodynamic
control,
this
emerged
as
an
essential
tool
for
synthesizing
nanomaterials
with
precisely
tunable
microstructures
morphologies.
This
paper
reviews
latest
advancements
controllable
synthesis
metal
nano‐electrocatalysts
utilizing
microfluidic
technology.
Firstly,
it
systematically
elucidates
fundamental
principles
distinctive
parameter
control
strategies.
Subsequently,
delves
deeply
into
mechanism
enhancement
process
nanoparticles
environment.
Through
analysis
specific
cases,
extensive
application
prospects
advantages
system
have
been
further
elucidated.
Finally,
summarizes
looks
forward
challenges
future
development
directions
that
faces
nano‐electrocatalysts.
review
aims
provide
valuable
insights
morphology
design
technological
innovation
electrocatalysts.
Abstract
The
development
of
next
generation
energy
storage
devices
with
low
self‐discharge
rate,
high
density
and
cost
are
the
requirements
to
meet
future
environmental
needs.
In
recent
years,
demand
has
risen
in
tandem
population
growth
technological
advancement.
Energy
resources
finite.
Thus,
solving
economic
difficulties
ensuring
their
continuous
efficient
consumption
will
require
new
research
technologies.
use
nanomaterials
improves
performance
its
morphologies
properties
like
surface
area,
tunable
pore
size,
good
ionic
conductive
properties.
It
also
plays
a
critical
role
by
improving
long
lifespan,
safety,
cyclicity
electrodes
materials.
This
short
review
brings
out
main
approaches
about
comprehensive
analysis
advances
prospect
for
technology
applications.
discusses
classification
i.
e.,
carbon‐based
materials,
metal‐oxides,
nanowires,
polymers,
etc.
impact
technologies
nanomaterials.
They
make
it
possible
occupy
all
intercalation
sites
particle
volume,
which
results
quick
ion
diffusion
specific
capacities.
Because
these
characteristics,
made
can
withstand
currents,
making
them
potential
option
storing
at
power
density.
related
market
study
predicts
that
worldwide
nanotechnology
sector
expand
from
an
estimated
$
139.7
million
2020
384.8
2030,
representing
CAGR
(compound
annual
rate)
10.7
percent
2021
2030.
Research
indicates
conversion
systems
using
more
efficient.
Carbon‐based
added
phase
change
materials
were
studied
charge
discharge
rates.
Prior
indicated
several
material
properties,
including
concentration,
form,
transition,
significantly
impacted
efficiency
composites.
article
summarises
current
state
knowledge
regarding
effective
conversion.
Finally,
uses
technologies,
wearable
flexible
electronics,
grid‐scale
storage,
electrochemical
different
applications
is
discussed.
