The
term
‘photocatalysis’
has
recently
gained
high
popularity,
and
various
products
using
photocatalytic
functions
have
been
commercialized.
Of
all
the
materials
that
may
be
used
as
photocatalysts,
TiO2
is
virtually
only
one
now
most
likely
will
remain
appropriate
for
industrial
application.
Water
air
purification
systems,
sterilization,
hydrogen
evolution,
self-cleaning
surfaces,
photoelectrochemical
conversion
are
just
a
few
of
applications
in
environmental
energy
domains
make
extensive
use
photocatalysis.
This
due
to
fact
lowest
cost,
stability,
effective
photoactivity.
Furthermore,
history
attests
its
safety
both
people
environment
because
it
white
pigment
since
antiquity.
review
discusses
some
important
aspects
issues
concerning
different
synthesis
methods
their
influence
on
structure
properties
TiO2,
well
concept
photocatalysis
based
promising
biocompatible
functional
material
widely
recent
years.
advantages
fields
science
technology
discussed,
including
protection,
water
liberation,
photovoltaic
energy,
cancer
diagnosis
therapy,
coatings
dental
products,
etc.
Information
phases,
modern
them
presented.
followed
by
detailed
basic
principles
with
brief
introduction
Finally,
challenges
prospects
briefly
discussed.
Recent
advances
fundamental
understanding
at
atomic-molecular
level
highlighted,
summarized
terms
design
engineering
new
materials.
Applied Sciences,
Journal Year:
2024,
Volume and Issue:
14(11), P. 4376 - 4376
Published: May 22, 2024
As
a
case
study
on
sustainable
energy
use
in
educational
institutions,
this
examines
the
design
and
integration
of
solar–hydrogen
storage
system
within
management
framework
Kangwon
National
University’s
Samcheok
Campus.
This
paper
provides
an
extensive
analysis
architecture
integrated
such
system,
which
is
necessary
given
increasing
focus
renewable
sources
requirement
for
effective
management.
starts
with
survey
literature
hydrogen
techniques,
solar
technologies,
current
university
systems.
In
order
to
pinpoint
areas
need
improvement
chances
progress,
it
also
looks
at
earlier
research
study’s
methodology
describes
architecture,
includes
fuel
cell
integration,
electrolysis
production,
harvesting,
storage,
customized
needs
university.
explores
consumption
characteristics
Campus
University
recommendations
scalability
scale
suggested
by
designing
three
systems
microgrids
EMS
Optimization
solar–hydrogen,
hybrid
storage.
To
guarantee
safe
functioning,
control
strategies
safety
considerations
are
covered.
Prototype
creation,
testing,
validation
all
part
implementation
process,
ends
thorough
system’s
into
university’s
grid.
The
effectiveness
its
effect
campus
patterns,
financial
sustainability,
comparisons
conventional
assessed
findings
discussion
section.
Problems
that
arise
during
addressed
along
fixes,
directions
further
research—such
as
issues
technology
developments—are
indicated.
sheds
important
light
viability
efficiency
academic
environments,
particularly
regard
accomplishing
objectives.
Energies,
Journal Year:
2024,
Volume and Issue:
17(17), P. 4514 - 4514
Published: Sept. 9, 2024
The
use
of
green
hydrogen
as
a
high-energy
fuel
the
future
may
be
an
opportunity
to
balance
unstable
energy
system,
which
still
relies
on
renewable
sources.
This
work
is
comprehensive
review
recent
advancements
in
production.
outlines
current
consumption
trends.
It
presents
tasks
and
challenges
economy
towards
hydrogen,
including
production,
purification,
transportation,
storage,
conversion
into
electricity.
main
types
water
electrolyzers:
alkaline
electrolyzers,
proton
exchange
membrane
solid
oxide
anion
electrolyzers.
Despite
higher
production
costs
compared
grey
this
suggests
that
technologies
become
cheaper
more
efficient,
cost
expected
decrease.
highlights
need
for
cost-effective
efficient
electrode
materials
large-scale
applications.
concludes
by
comparing
operating
parameters
considerations
different
electrolyzer
technologies.
sets
targets
2050
improve
efficiency,
durability,
scalability
underscores
importance
ongoing
research
development
address
limitations
technology
make
competitive
with
fossil
fuels.
Energies,
Journal Year:
2025,
Volume and Issue:
18(5), P. 1167 - 1167
Published: Feb. 27, 2025
This
paper
presents
a
thorough
initial
evaluation
of
hydrogen
gaseous
storage
and
pipeline
infrastructure,
emphasizing
health
safety
protocols
as
well
capacity
considerations
pertinent
to
industrial
applications.
As
increasingly
establishes
itself
vital
energy
vector
within
the
transition
towards
low-carbon
systems,
formulation
effective
transportation
solutions
becomes
imperative.
The
investigation
delves
into
applications
technologies
associated
with
storage,
specifically
concentrating
on
compressed
gas
elucidating
principles
underlying
compression
diverse
categories
tanks,
including
pressure
vessels
designed
for
containment.
Critical
factors
concerning
pipelines
are
scrutinized,
accompanied
by
review
appropriate
apparatus,
types
compressors,
particular
specifications
necessary
transport
both
oxygen
generated
electrolysers.
significance
in
systems
is
underscored
due
flammable
nature
high
diffusivity
hydrogen.
defines
recommended
operations,
alongside
exemplary
practices
implementation
these
across
various
configurations.
Moreover,
it
investigates
function
produced
from
electrolysers,
considering
interconnected
standards
governing
infrastructure.
conclusions
drawn
this
study
facilitate
advancement
secure
efficient
thereby
furthering
overarching
aim
scalable
deployment
sectors.
