Chemical Reviews,
Год журнала:
2022,
Номер
122(12), С. 11085 - 11130
Опубликована: Апрель 27, 2022
Since
the
seminal
works
on
application
of
density
functional
theory
and
computational
hydrogen
electrode
to
electrochemical
CO2
reduction
(eCO2R)
evolution
(HER),
modeling
both
reactions
has
quickly
evolved
for
last
two
decades.
Formulation
thermodynamic
kinetic
linear
scaling
relationships
key
intermediates
crystalline
materials
have
led
definition
activity
volcano
plots,
overpotential
diagrams,
full
exploitation
these
theoretical
outcomes
at
laboratory
scale.
However,
recent
studies
hint
role
morphological
changes
short-lived
in
ruling
catalytic
performance
under
operating
conditions,
further
raising
bar
electrocatalytic
systems.
Here,
we
highlight
some
novel
methodological
approaches
employed
address
eCO2R
HER
reactions.
Moving
from
atomic
scale
bulk
electrolyte,
first
show
how
ab
initio
machine
learning
methodologies
can
partially
reproduce
surface
reconstruction
operation,
thus
identifying
active
sites
reaction
mechanisms
if
coupled
with
microkinetic
modeling.
Later,
introduce
potential
interpret
data
Operando
spectroelectrochemical
techniques,
such
as
Raman
spectroscopy
extended
X-ray
absorption
fine
structure
characterization.
Next,
review
electrolyte
mass
transport
effects.
Finally,
suggest
challenges
near
future
well
our
perspective
directions
follow.
Abstract
Single‐atom
catalysts
(SACs)
provide
well‐defined
active
sites
with
100%
atom
utilization,
and
can
be
prepared
using
a
wide
range
of
support
materials.
Therefore,
they
are
attracting
global
attention,
especially
in
the
fields
energy
conversion
storage.
To
date,
research
has
focused
on
transition‐metal
precious‐metal‐based
SACs.
More
recently,
rare‐earth
(RE)‐based
SACs
have
emerged
as
new
frontier
photo/electrocatalysis
owing
to
their
unique
electronic
structure
arising
from
spin‐orbit
coupling
4f
valence
orbitals,
unsaturated
coordination
environment,
behavior
charge‐transport
bridges.
However,
systematic
review
role
RE
sites,
catalytic
mechanisms,
synthetic
methods
for
is
lacking.
this
review,
latest
developments
having
applications
summarized
discussed.
First,
theoretical
advantages
briefly
introduced,
focusing
roles
orbitals
coupled
levels.
In
addition,
most
recent
progress
several
important
photo/electrocatalytic
reactions
corresponding
mechanisms
Further,
strategies
production
reported.
Finally,
challenges
development
highlighted,
along
future
directions
perspectives.
Nano-Micro Letters,
Год журнала:
2022,
Номер
15(1)
Опубликована: Дек. 6, 2022
As
a
flourishing
member
of
the
two-dimensional
(2D)
nanomaterial
family,
MXenes
have
shown
great
potential
in
various
research
areas.
In
recent
years,
continued
growth
interest
MXene
derivatives,
2D
transition
metal
borides
(MBenes),
has
contributed
to
emergence
this
material
as
latecomer.
Due
excellent
electrical
conductivity,
mechanical
properties
and
properties,
thus
MBenes
attract
more
researchers'
interest.
Extensive
experimental
theoretical
studies
that
they
exciting
energy
conversion
electrochemical
storage
potential.
However,
comprehensive
systematic
review
applications
not
been
available
so
far.
For
reason,
we
present
summary
advances
research.
We
started
by
summarizing
latest
fabrication
routes
MBenes.
The
focus
will
then
turn
their
for
conversion.
Finally,
brief
challenges
opportunities
future
practical
is
presented.
Advanced Energy Materials,
Год журнала:
2022,
Номер
12(20)
Опубликована: Март 29, 2022
Abstract
The
solar‐energy‐driven
photoreduction
of
CO
2
has
recently
emerged
as
a
promising
approach
to
directly
transform
into
valuable
energy
sources
under
mild
conditions.
As
clean‐burning
fuel
and
drop‐in
replacement
for
natural
gas,
CH
4
is
an
ideal
product
photoreduction,
but
the
development
highly
active
selective
semiconductor‐based
photocatalysts
this
important
transformation
remains
challenging.
Hence,
significant
efforts
have
been
made
in
search
active,
selective,
stable,
sustainable
photocatalysts.
In
review,
recent
applications
cutting‐edge
experimental
computational
materials
design
strategies
toward
discovery
novel
catalysts
photocatalytic
conversion
are
systematically
summarized.
First,
insights
effective
catalyst
engineering
strategies,
including
heterojunctions,
defect
engineering,
cocatalysts,
surface
modification,
facet
single
atoms,
presented.
Then,
data‐driven
photocatalyst
spanning
density
functional
theory
(DFT)
simulations,
high‐throughput
screening,
machine
learning
(ML)
presented
through
step‐by‐step
introduction.
combination
DFT,
ML,
experiments
emphasized
powerful
solution
accelerating
reduction
.
Last,
challenges
perspectives
concerning
interplay
between
rational
industrialization
large‐scale
technologies
described.
Rechargeable
aqueous
Zn–CO
2
batteries
show
great
promise
in
meeting
severe
environmental
problems
and
energy
crises
due
to
their
combination
of
CO
utilization
output,
as
well
advantages
high
theoretical
density,
abundant
raw
materials,
safety.
Developing
high‐efficiency
stable
reduction
reaction
(CO
RR)
electrocatalysts
is
critical
importance
for
the
promotion
this
technology.
Atomically
dispersed
metal‐based
catalysts
(ADMCs),
with
extremely
atom‐utilization
efficiency,
tunable
coordination
environments,
superior
intrinsic
catalytic
activity,
are
emerging
promising
candidates
batteries.
Herein,
some
recent
developments
atomically
summarized,
including
transition
metal
non‐transition
sites.
Moreover,
various
synthetic
strategies,
characterization
methods,
relationship
between
active
site
structures
RR
activity/Zn–CO
battery
performance
introduced.
Finally,
challenges
perspectives
also
proposed
future
development
ADMCs
Nano-Micro Letters,
Год журнала:
2023,
Номер
15(1)
Опубликована: Окт. 13, 2023
Abstract
Efficient
electrocatalysts
are
crucial
for
hydrogen
generation
from
electrolyzing
water.
Nevertheless,
the
conventional
"trial
and
error"
method
producing
advanced
is
not
only
cost-ineffective
but
also
time-consuming
labor-intensive.
Fortunately,
advancement
of
machine
learning
brings
new
opportunities
discovery
design.
By
analyzing
experimental
theoretical
data,
can
effectively
predict
their
evolution
reaction
(HER)
performance.
This
review
summarizes
recent
developments
in
low-dimensional
electrocatalysts,
including
zero-dimension
nanoparticles
nanoclusters,
one-dimensional
nanotubes
nanowires,
two-dimensional
nanosheets,
as
well
other
electrocatalysts.
In
particular,
effects
descriptors
algorithms
on
screening
investigating
HER
performance
highlighted.
Finally,
future
directions
perspectives
electrocatalysis
discussed,
emphasizing
potential
to
accelerate
electrocatalyst
discovery,
optimize
performance,
provide
insights
into
electrocatalytic
mechanisms.
Overall,
this
work
offers
an
in-depth
understanding
current
state
its
research.
The Journal of Physical Chemistry Letters,
Год журнала:
2022,
Номер
13(34), С. 7920 - 7930
Опубликована: Авг. 18, 2022
Designing
and
screening
novel
electrocatalysts,
understanding
electrocatalytic
mechanisms
at
an
atomic
level,
uncovering
scientific
insights
lie
the
center
of
development
electrocatalysis.
Despite
certain
success
in
experiments
computations,
it
is
still
difficult
to
achieve
above
objectives
due
complexity
systems
vastness
chemical
space
for
candidate
electrocatalysts.
With
advantage
machine
learning
(ML)
increasing
interest
electrocatalysis
energy
conversion
storage,
data-driven
research
motivated
by
artificial
intelligence
(AI)
has
provided
new
opportunities
discover
promising
investigate
dynamic
reaction
processes,
extract
knowledge
from
huge
data.
In
this
Perspective,
we
summarize
recent
applications
ML
electrocatalysis,
including
electrocatalysts
simulation
processes.
Furthermore,
interpretable
methods
are
discussed
accelerate
generation.
Finally,
blueprint
envisaged
future
ACS Catalysis,
Год журнала:
2023,
Номер
13(14), С. 9616 - 9628
Опубликована: Июль 7, 2023
Electrocatalytic
CO2
reduction
reactions
(CO2RR)
based
on
scalable
and
highly
efficient
catalysis
provide
an
attractive
strategy
for
reducing
emissions.
In
this
work,
we
combined
first-principles
density
functional
theory
(DFT)
machine
learning
(ML)
to
comprehensively
explore
the
potential
of
double-atom
catalysts
(DACs)
featuring
inverse
sandwich
structure
anchored
defective
graphene
(gra)
catalyze
CO2RR
generate
C1
products.
We
started
with
five
homonuclear
M2⊥gra
(M
=
Co,
Ni,
Rh,
Ir,
Pt),
followed
by
127
heteronuclear
MM′⊥gra
Pt,
M′
Sc–Au).
Stable
DACs
were
screened
evaluating
their
binding
energy,
formation
dissolution
metal
atoms,
as
well
conducting
molecular
dynamics
simulations
without
solvent
water
molecules.
Based
DFT
calculations,
Rh2⊥gra
DAC
was
found
outperform
other
four
Rh-based
single-
noninverse
structures.
Out
DACs,
14
be
stable
have
good
catalytic
performance.
An
ML
approach
adopted
correlate
key
factors
activity
stability
including
sum
radii
ligand
atoms
(dM–M′,
dM–C,
dM′–C),
difference
electronegativity
two
(PM
+
PM′,
PM
–
PM′),
first
ionization
energy
(IM
IM′,
IM
IM′),
electron
affinity
(AM
AM′,
AM
AM′),
number
d-electrons
(Nd).
The
obtained
models
further
used
predict
154
electrocatalysts
out
784
possible
same
configuration.
Overall,
work
not
only
identified
promising
reported
but
also
provided
insights
into
atomic
characteristics
associated
high
activity.
Traditional
trial-and-error
experiments
and
theoretical
simulations
have
difficulty
optimizing
catalytic
processes
developing
new,
better-performing
catalysts.
Machine
learning
(ML)
provides
a
promising
approach
for
accelerating
catalysis
research
due
to
its
powerful
predictive
abilities.
The
selection
of
appropriate
input
features
(descriptors)
plays
decisive
role
in
improving
the
accuracy
ML
models
uncovering
key
factors
that
influence
activity
selectivity.
This
review
introduces
tactics
utilization
extraction
descriptors
ML-assisted
experimental
research.
In
addition
effectiveness
advantages
various
descriptors,
their
limitations
are
also
discussed.
Highlighted
both
1)
newly
developed
spectral
performance
prediction
2)
novel
paradigm
combining
computational
through
suitable
intermediate
descriptors.
Current
challenges
future
perspectives
on
application
techniques
presented.
