Abstract
Amid
the
global
energy
crisis
and
rising
emphasis
on
sustainability,
efficient
harvesting
has
become
a
research
priority.
Nanogenerators
excel
in
converting
abundant
mechanical
thermal
into
electricity,
offering
promising
path
for
sustainable
solutions.
Among
various
nanogenerator's
materials,
Polyvinylidene
fluoride
(PVDF),
with
its
distinctive
molecular
structure,
exhibits
multifunctional
electrical
properties
including
dielectric,
piezoelectric
pyroelectric
characteristics.
These
combined
excellent
flexibility
make
PVDF
prime
candidate
material
nanogenerators.
In
nanogenerators,
this
is
capable
of
efficiently
collecting
energy.
This
paper
discusses
how
PVDF's
are
manifested
three
types
nanogenerators
compares
performance
these
addition,
strategies
to
improve
output
demonstrated,
physical
chemical
modification
as
well
structural
optimization
such
hybrid
structures
external
circuits.
It
also
introduces
application
natural
human
harvesting,
prospects
medical
technologies
smart
home
systems.
The
aim
promote
use
self‐powered
sensing,
monitoring,
thereby
providing
valuable
insights
designing
more
versatile
Advanced Sensor Research,
Год журнала:
2024,
Номер
unknown
Опубликована: Июнь 17, 2024
Abstract
Sensors
play
a
crucial
role
in
enhancing
the
quality
of
life,
ensuring
safety,
and
facilitating
technological
advancements.
Over
past
decade,
2D
layered
materials
have
been
added
as
new
sensing
element
addition
to
existing
such
metal
oxides,
semiconductors,
metals,
polymers.
Layered
are
typically
characterized
by
their
single
or
few‐layer
thickness
offer
high
surface‐to‐volume
ratio,
exceptional
mechanical
strength,
unique
electronic
attributes.
These
properties
make
them
ideal
candidates
for
variety
applications.
This
review
article
focused
on
utilizing
triboelectric
nanogenerators
(TENGs)
different
The
best
part
TENG‐based
is
that
it
self‐powered,
so
no
external
power
supply
required.
initial
importance
innovative
integration
methods
TENGs.
Further,
this
discusses
various
applications,
including
humidity,
touch,
force,
temperature,
gas
sensing,
highlighting
impact
sensitivity
selectivity
TENG
sensors.
last
challenges
prospects
self‐powered
Advanced Sustainable Systems,
Год журнала:
2024,
Номер
unknown
Опубликована: Июль 23, 2024
Abstract
Smart
textiles
represent
a
revolutionary
approach
to
wearable
technology
with
applications
ranging
from
healthcare
energy
harvesting.
This
review
paper
explores
the
importance
of
textile
technologies
and
highlights
their
potential
revolutionize
consumer
electronics.
Conventional
are
sometimes
heavy,
lack
comfort
flexibility,
but
smart
seamlessly
integrate
into
everyday
clothing,
improving
wearability
user
experience.
The
article
emphasizes
need
for
sustainable
sourcing
environmentally
friendly
production
methods,
as
well
responsible
manufacturing
disposal
practices.
Manufacturing
techniques
such
wet
spinning,
melt
electrostatic
weaving,
knitting,
printing
detailed
shed
light
on
role
in
incorporating
electronics
textiles.
Several
textile‐based
devices
being
explored,
including
biochemical
sensing,
temperature
monitoring,
harvesting,
storage,
displays.
Each
application
demonstrates
versatility
different
areas.
Despite
optimistic
progress,
challenges
remain,
efficiency
protecting
privacy
data
security.
analyzes
these
problems
suggests
future
improvements,
interdisciplinary
collaboration
find
new
solutions.
Finally,
an
overview
current
state
provides
this
technology.
It
serves
in‐depth
reference
academics
readers
interested
understanding
recent
advances
discoveries
technologies,
highlighting
rapidly
growing
industry.
Abstract
Amid
the
global
energy
crisis
and
rising
emphasis
on
sustainability,
efficient
harvesting
has
become
a
research
priority.
Nanogenerators
excel
in
converting
abundant
mechanical
thermal
into
electricity,
offering
promising
path
for
sustainable
solutions.
Among
various
nanogenerator's
materials,
Polyvinylidene
fluoride
(PVDF),
with
its
distinctive
molecular
structure,
exhibits
multifunctional
electrical
properties
including
dielectric,
piezoelectric
pyroelectric
characteristics.
These
combined
excellent
flexibility
make
PVDF
prime
candidate
material
nanogenerators.
In
nanogenerators,
this
is
capable
of
efficiently
collecting
energy.
This
paper
discusses
how
PVDF's
are
manifested
three
types
nanogenerators
compares
performance
these
addition,
strategies
to
improve
output
demonstrated,
physical
chemical
modification
as
well
structural
optimization
such
hybrid
structures
external
circuits.
It
also
introduces
application
natural
human
harvesting,
prospects
medical
technologies
smart
home
systems.
The
aim
promote
use
self‐powered
sensing,
monitoring,
thereby
providing
valuable
insights
designing
more
versatile
