Crystals,
Journal Year:
2024,
Volume and Issue:
14(7), P. 597 - 597
Published: June 27, 2024
One
of
the
key
environmental
problems
underlying
climate
change
and
global
warming
is
persistent
increase
in
atmospheric
carbon
dioxide
concentration.
Carbon
capture
storage
(CCS)
systems
can
be
based
on,
among
others,
solid
porous
sorbents
(e.g.,
zeolites).
A
promising
alternative
to
traditionally
used
may
appropriately
structured
hybrid
adsorbents.
With
proper
geometry
synergistic
combination
sorbent
with
another
material,
e.g.,
a
catalyst
or
substance
certain
useful
physical
features,
they
gain
new
properties.
The
present
study
examined
dynamics
CO2
sorption
core–shell
particles
and,
as
reference,
uniform
structure.
It
was
assumed
that
(zeolite
5A)
incorporated
single
particle
had
form
microcrystals,
which
implies
bidisperse
As
second
particle-forming
nickel
(behaving
an
inert)
adopted.
computational
results
confirmed
structure
provide
additional
design
parameter
for
adsorption
columns
adsorptive
reactors.
sorption-inactive
shell
proved
play
protective
role
when
thermal
waves
moved
through
bed.
In
addition,
important
element
determining
revealed
mean
pore
diameter)
controlling
intraparticle
mass
transport.
Frontiers in Energy Research,
Journal Year:
2024,
Volume and Issue:
12
Published: Oct. 15, 2024
Carbon
Capture
and
Storage
(CCS)
is
recognized
as
a
potent
strategy
for
managing
the
accumulation
of
human-generated
CO
2
in
atmosphere,
helping
to
alleviate
climate
change’s
effects.
The
gas
captured
from
point
source
through
methods
such
pre-treating
fossil
fuels,
oxy-fuel
combustion,
or
post-combustion
capture;
thereafter;
it
transported
storage
location
injected
into
geological
formations.
This
article
provides
an
overview
carbon
dioxide
capture
sequestration,
focusing
on
its
key
principles,
technologies,
associated
risks,
challenges.
Direct
Air
(DAC)
Scalable
Modelling,
Artificial
intelligence
(Al),
Rapid
Theoretical
calculations
SMART
technologies
are
detailed
emerging
promising
approaches
capture.
Numerous
pilot
commercial
projects
commissioned
manage
emissions
presented.
Additionally,
paper
explores
combining
geological,
geophysical,
geochemical,
environmental
monitoring
techniques
ensure
secure
sustainable
underground.
These
essential
address
uncertainties,
minimize
build
public
confidence
CCS
viable
mitigation
strategy.
successful
deployment
these
global
scale
will
require
continued
innovation,
particularly
areas
monitoring,
risk
management,
engagement.
Emerging
AI
systems
could
play
crucial
role
enhancing
efficiency
safety
operations.
However,
integration
advancements
with
existing
infrastructure
regulatory
frameworks
remains
challenge.
Ultimately,
multi-disciplinary
approach,
technological,
economic,
perspectives,
be
vital
realizing
full
potential
combating
change.
Crystals,
Journal Year:
2024,
Volume and Issue:
14(7), P. 597 - 597
Published: June 27, 2024
One
of
the
key
environmental
problems
underlying
climate
change
and
global
warming
is
persistent
increase
in
atmospheric
carbon
dioxide
concentration.
Carbon
capture
storage
(CCS)
systems
can
be
based
on,
among
others,
solid
porous
sorbents
(e.g.,
zeolites).
A
promising
alternative
to
traditionally
used
may
appropriately
structured
hybrid
adsorbents.
With
proper
geometry
synergistic
combination
sorbent
with
another
material,
e.g.,
a
catalyst
or
substance
certain
useful
physical
features,
they
gain
new
properties.
The
present
study
examined
dynamics
CO2
sorption
core–shell
particles
and,
as
reference,
uniform
structure.
It
was
assumed
that
(zeolite
5A)
incorporated
single
particle
had
form
microcrystals,
which
implies
bidisperse
As
second
particle-forming
nickel
(behaving
an
inert)
adopted.
computational
results
confirmed
structure
provide
additional
design
parameter
for
adsorption
columns
adsorptive
reactors.
sorption-inactive
shell
proved
play
protective
role
when
thermal
waves
moved
through
bed.
In
addition,
important
element
determining
revealed
mean
pore
diameter)
controlling
intraparticle
mass
transport.
