Energy Technology,
Год журнала:
2024,
Номер
unknown
Опубликована: Дек. 10, 2024
The
tremendous
advancements
in
science
and
technology
have
resulted
the
invention
of
electronic
devices
that
require
greater
energy
storage
capabilities.
Hybrid
supercapacitors
(SCs)
gain
promising
interest
due
to
their
exceptional
electrochemical
performance
similar
batteries
(high‐energy
density)
SCs
(high‐power
density).
excellent
electrode
material
is
significantly
influenced
by
employed
synthesis
route.
copper
phosphate
(Cu
3
(PO
4
)
2
nanomaterials
are
synthesized
using
hydrothermal
sonochemical
techniques.
Two‐
three‐electrode
configurations
utilized
evaluate
as‐prepared
nanomaterials.
An
incredible
specific
capacity
443.86
C
g
−1
at
1.4
A
achieved
through
sonochemically
obtained
nanomaterial
(S2).
In
two‐electrode
configuration,
S2
used
as
a
positive
fabricate
an
asymmetric
device,
which
provides
density
51.2
Wh
kg
power
6800
W
0.9
8.0
,
respectively.
device
also
demonstrates
retention
93.45%
after
1000
galvanostatic
charge–discharge
cycles
5
.
Overall,
outcomes
suggest
method
most
effective
approach
for
preparation
next‐generation
applications.
Metal-organic
frameworks
(MOFs)
represent
a
highly
promising
material
class
for
bioelectronic
supercapacitors,
characterized
by
their
adjustable
structures,
extensive
surface
areas,
and
superior
electrochemical
properties.
This
research
explores
the
synthesis
incorporation
of
MOF-based
materials
into
devices
aimed
at
energy
storage
biosensing
applications.
The
focus
is
on
improving
performance
MOFs
while
preserving
structural
integrity
through
functionalization
with
biocompatible
polymers
conductive
materials.
resulting
supercapacitors
exhibit
significant
improvements
in
specific
capacitance,
density,
cycling
stability.
Additionally,
inclusion
bioreceptors
allows
simultaneous
detection
biochemical
signals
alongside
storage,
thus
enabling
innovative
applications
wearable
electronics
health
monitoring
systems.
These
results
suggest
that
have
capacity
to
fulfill
needs
also
advancing
bioelectronics
merging
sensing
capabilities.
Abstract
Metal‐organic
frameworks
(MOFs)
have
gained
prominence
through
reticular
chemistry,
connecting
building
blocks
to
create
specific
structures.
MOFs
offer
high
surface
areas,
porosity,
stability,
and
diverse
functionalities.
This
makes
them
easily
modifiable
for
various
applications,
evolving
into
complex
architectures.
Recent
advancements
in
MOF‐derived
multi‐shelled
nanostructures
are
summarized
herein.
The
advantages
disadvantages
of
these
over
bare
single‐shelled
structures
discussed.
recent
progress
potential
energy
storage
applications
comprehensively
explored.
Challenges
prospects
this
area
also
outlined.
