In-situ characterization technologies and theoretical calculations in carbon dioxide reduction: In-depth understanding of reaction mechanisms and rational design of electrocatalysts
Coordination Chemistry Reviews,
Год журнала:
2025,
Номер
533, С. 216541 - 216541
Опубликована: Фев. 28, 2025
Язык: Английский
2024, A Landmark Year for Climate Change and Global Carbon Capture, Utilization, and Storage: Annual Progress Review
Energy Science & Engineering,
Год журнала:
2025,
Номер
unknown
Опубликована: Апрель 4, 2025
ABSTRACT
This
annual
review
outlines
the
progress
of
carbon
capture,
utilization,
and
storage
(CCUS)
technologies
in
2024.
As
human‐induced
CO
2
emissions
continued
to
rise,
year
presented
critical
challenges.
Notably,
2024
was
hottest
on
record
first
which
global
temperatures
exceeded
preindustrial
levels
by
more
than
1.5°C,
driving
intensified
efforts
advance
CCUS.
Scientific
interest
CCUS
grew
significantly,
with
number
related
publications
increasing
11.4%
compared
2023,
reaching
53,970.
The
total
operational
commercial
facilities
also
expanded,
rising
16.3%
a
50.
In
political
area,
governments
introduced
targeted
policies
accelerate
adoption,
focusing
economic
investment
specific
implementation
requirements.
Язык: Английский
Heterogeneous Electrocatalytic CO2 Reduction by Supported Molecular Catalysts Well Dispersed on Electrode Surface
ChemElectroChem,
Год журнала:
2025,
Номер
unknown
Опубликована: Апрель 22, 2025
Electrochemical
CO
2
reduction
(CO
R)
to
value‐added
products
using
renewable
electricity
offers
a
promising
approach
toward
achieving
carbon
neutrality.
Among
various
electrocatalysts,
molecular
catalysts,
particularly
transition
metal
complexes,
stand
out
due
the
high
selectivity
for
single
specific
and
desirable
tunability,
enabling
rational
optimization
of
catalytic
performance.
However,
their
practical
application
is
hindered
by
low
operating
current
densities
challenges
in
catalyst
recycling.
To
address
these
limitations,
immobilizing
catalysts
on
electrode
surfaces
has
emerged
as
an
effective
strategy
integrating
selective
into
heterogeneous
catalysis.
This
mini
review
focuses
distinct
category
heterogenized
catalysts—those
molecularly
dispersed
supported
substrates
or
surfaces‐which
exhibit
remarkable
activity
at
single‐molecule
level
ability
drive
deep
(beyond
two
electrons)
under
certain
conditions.
Recent
progress
this
field
comprehensively
discussed,
emphasizing
critical
impacts
molecule‐level
dispersion
catalyst‐support
interactions
electronic
properties,
multi‐electron
transfer
kinetics,
overall
Moreover,
overview
potential
applications
beyond
electrochemical
R
provided
end.
aims
offer
valuable
insights
future
design
efficient
scalable
electrocatalysts
sustainable
conversion.
Язык: Английский
Industrial‐Level Modulation of Catalyst‐Electrolyte Microenvironment for Electrocatalytic CO2 Reduction: Challenges and Advancements
Advanced Energy Materials,
Год журнала:
2024,
Номер
unknown
Опубликована: Сен. 9, 2024
Abstract
CO
2
reduction
reaction
(CO
RR),
as
a
promising
strategy
for
storing
renewable
energy
and
promoting
carbon
resource
recycling,
is
critical
industrial
development.
Previous
reports
have
extensively
explored
catalyst‐electrolyte
microenvironmental
modulation
to
elucidate
coupling
mechanisms
enhance
catalytic
conversion
multicarbon
products.
Currently,
most
reviews
mainly
focus
on
the
impact
of
microenvironment
in
low‐current
systems
mechanism
exploration
performance
optimization,
yet
few
them
can
integrate
macroscopic
applications
with
microscopic
investigations
explore
relevance
between
development
optimization.
To
address
gap,
this
review
focuses
summarizing
challenges
advancements
high‐current
devices.
By
introducing
models
different
scales
sequentially,
connection
device
clarified.
Then,
various
invalidation
effective
solutions
are
summarized
intuitively
expound
stability.
Meanwhile,
an
intuitive
measure
rationality
modulation,
evaluation
methods
should
be
refined,
which
also
covered
further
detail
below.
Finally,
more
valuable
challenging
prospects
discussed
guiding
transformation
RR.
Язык: Английский