Energy Technology,
Journal Year:
2024,
Volume and Issue:
unknown
Published: Dec. 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.
RSC Advances,
Journal Year:
2024,
Volume and Issue:
14(45), P. 32958 - 32977
Published: Jan. 1, 2024
To
address
the
inherent
challenges
such
as
restacking,
limited
ion-accessibility,
scalability,
stability,
and
intricate
balance
between
surface
area
conductivity,
this
article
delves
into
emerging
strategies
prospects.
Sustainable Energy & Fuels,
Journal Year:
2024,
Volume and Issue:
8(18), P. 4355 - 4364
Published: Jan. 1, 2024
A
Co-MOF
assembled
hybrid
supercapacitor
exhibits
outstanding
specific
energy
and
power
(60.07
W
h
kg
−1
850
)
with
80.01%
diffusive
76.72%
capacitive
contribution
at
3
100
mV
s
,
respectively.
RSC Advances,
Journal Year:
2024,
Volume and Issue:
14(46), P. 33941 - 33951
Published: Jan. 1, 2024
Metal-organic
frameworks
(MOFs)
have
garnered
substantial
attention
as
promising
candidates
for
electrode
materials
due
to
their
intriguing
electrochemical
properties.
However,
the
quest
enhanced
energy
density
and
electrical
conductivity
persists.
Manipulating
surface
morphology
emerges
a
pivotal
strategy
modulate
these
attributes
unlock
full
potential
of
MOFs
in
applications.
This
research
delves
into
pioneering
exploration
copper
metal-organic
framework
synthesis
employing
pyridine-4-carboxylic
acid
RSC Advances,
Journal Year:
2025,
Volume and Issue:
15(15), P. 11441 - 11450
Published: Jan. 1, 2025
In
this
work,
to
address
the
issue
of
poor
conductivity
in
COFs,
a
layered
porous
composite
(EG@COF)
was
successfully
synthesized.
A
redox-active
COF
(DAAQ-TFP
COF)
grown
on
surface
expanded
graphite
(EG)
through
solvent-free
situ
synthesis.
SEM
analysis
displayed
that
obtained
possessed
structure.
Further
investigations
revealed
EG
not
only
improved
electrical
but
also
regulated
pore
size
COFs.
This
structure
highly
conducive
enhancing
specific
capacitance
electrode
material.
An
electrochemical
study
demonstrated
EG@COF-3
reached
351
C
g-1
at
1
g-1,
with
94.4%
retention
after
10
000
cycles.
The
excellent
attributed
stable
backbone
COF.
Meanwhile,
an
asymmetric
supercapacitor
(ACS)
comprising
activated
carbon
(AC)
and
EG@COF
exhibited
energy
density
16.4
W
h
kg-1
power
806.0
kg-1.
Dalton Transactions,
Journal Year:
2025,
Volume and Issue:
unknown
Published: Jan. 1, 2025
To
address
challenges
like
limited
conductivity,
stability,
and
rate
capability
we
have
introduced
a
drive
towards
bi-linker
approach
to
engineer
MOFs,
tailoring
their
morphological
electrochemical
aspects.
