Advanced Materials,
Journal Year:
2022,
Volume and Issue:
35(4)
Published: June 23, 2022
Abstract
The
rapid
growth
of
the
electronics
industry
and
proliferation
electronic
materials
telecommunications
technologies
has
led
to
release
a
massive
amount
untreated
waste
(e‐waste)
into
environment.
Consequently,
catastrophic
environmental
damage
at
microbiome
level
serious
human
health
diseases
threaten
natural
fate
planet.
Currently,
demand
for
wearable
applications
in
personalized
medicine,
skins
(e‐skins),
monitoring
is
substantial
growing.
Therefore,
“green”
characteristics
such
as
biodegradability,
self‐healing,
biocompatibility
ensure
future
application
e‐skins
biomedical
engineering
bioanalytical
sciences.
Leveraging
sustainability,
will
dramatically
influence
fabrication
environmentally
friendly
electronics.
Here,
molecular
structural
biological
artificial
are
discussed.
focus
then
turns
biodegradable
materials,
including
synthetic‐polymer‐based
their
recent
development
e‐skin
sensors,
robotics,
human–machine
interfaces
(HMIs).
Finally,
main
challenges
outlook
regarding
preparation
critically
discussed
near‐future
scenario,
which
expected
lead
next
generation
e‐skins.
Advanced Science,
Journal Year:
2022,
Volume and Issue:
9(10)
Published: Jan. 31, 2022
Abstract
Rapid
advances
in
wearable
electronics
and
mechno‐sensational
human–machine
interfaces
impose
great
challenges
developing
flexible
deformable
tactile
sensors
with
high
efficiency,
ultra‐sensitivity,
environment‐tolerance,
self‐sustainability.
Herein,
a
hydrogel
sensor
(THS)
based
on
micro‐pyramid‐patterned
double‐network
(DN)
ionic
organohydrogels
to
detect
subtle
pressure
changes
by
measuring
the
variations
of
triboelectric
output
signal
without
an
external
power
supply
is
reported.
By
first
time
pyramidal‐patterned
fabrication
method
laminated
polydimethylsiloxane
(PDMS)
encapsulation
process,
self‐powered
THS
shows
advantages
remarkable
flexibility,
good
transparency
(≈85%),
excellent
sensing
performance,
including
extraordinary
sensitivity
(45.97
mV
Pa
−1
),
fast
response
(≈20
ms),
very
low
limit
detection
(50
Pa)
as
well
stability
(36
000
cycles).
Moreover,
LiBr
immersion
treatment
method,
possesses
long‐term
hyper
anti‐freezing
anti‐dehydrating
properties,
broad
environmental
tolerance
(−20
60
°C),
instantaneous
peak
density
20
µW
cm
−2
,
providing
reliable
contact
outputs
different
materials
detecting
slight
human
motions.
integrating
acquisition/process
circuit,
self‐power
ability
utilized
switching
button
control
electric
appliances
robotic
hands
simulating
finger
gestures,
offering
its
potentials
for
multi‐functional
electronic
applications.
Advanced Energy Materials,
Journal Year:
2022,
Volume and Issue:
13(1)
Published: Nov. 18, 2022
Abstract
The
advancement
of
the
Internet
Things/5G
infrastructure
requires
a
low‐cost
ubiquitous
sensory
network
to
realize
an
autonomous
system
for
information
collection
and
processing,
aiming
at
diversified
applications
ranging
from
healthcare,
smart
home,
industry
4.0
environmental
monitoring.
triboelectric
nanogenerator
(TENG)
is
considered
most
promising
technology
due
its
self‐powered,
cost‐effective,
highly
customizable
advantages.
Through
use
wearable
electronic
devices,
advanced
TENG
developed
as
core
enabling
self‐powered
sensors,
power
supplies,
data
communications
aforementioned
applications.
In
this
review,
advancements
TENG‐based
electronics
regarding
materials,
material/device
hybridization,
systems
integration,
convergence,
in
environment
monitoring,
transportation,
homes
toward
future
green
earth
are
reported.
Advanced Science,
Journal Year:
2021,
Volume and Issue:
8(14)
Published: May 26, 2021
Rapid
advancements
of
artificial
intelligence
things
(AIoT)
technology
pave
the
way
for
developing
a
digital-twin-based
remote
interactive
system
advanced
robotic-enabled
industrial
automation
and
virtual
shopping.
The
embedded
multifunctional
perception
is
urged
better
interaction
user
experience.
To
realize
such
system,
smart
soft
robotic
manipulator
presented
that
consists
triboelectric
nanogenerator
tactile
(T-TENG)
length
(L-TENG)
sensor,
as
well
poly(vinylidene
fluoride)
(PVDF)
pyroelectric
temperature
sensor.
With
aid
machine
learning
(ML)
data
processing,
fusion
T-TENG
L-TENG
sensors
can
automatic
recognition
grasped
objects
with
accuracy
97.143%
28
different
shapes
objects,
while
distribution
also
be
obtained
through
By
leveraging
IoT
(AI)
analytics,
shop
successfully
implemented
to
provide
users
real-time
feedback
about
details
product.
In
general,
by
offering
more
immersive
experience
in
human-machine
interactions,
proposed
shows
great
potential
being
interface
applications
unmanned
working
space.
Advanced Materials,
Journal Year:
2022,
Volume and Issue:
35(4)
Published: June 23, 2022
Abstract
The
rapid
growth
of
the
electronics
industry
and
proliferation
electronic
materials
telecommunications
technologies
has
led
to
release
a
massive
amount
untreated
waste
(e‐waste)
into
environment.
Consequently,
catastrophic
environmental
damage
at
microbiome
level
serious
human
health
diseases
threaten
natural
fate
planet.
Currently,
demand
for
wearable
applications
in
personalized
medicine,
skins
(e‐skins),
monitoring
is
substantial
growing.
Therefore,
“green”
characteristics
such
as
biodegradability,
self‐healing,
biocompatibility
ensure
future
application
e‐skins
biomedical
engineering
bioanalytical
sciences.
Leveraging
sustainability,
will
dramatically
influence
fabrication
environmentally
friendly
electronics.
Here,
molecular
structural
biological
artificial
are
discussed.
focus
then
turns
biodegradable
materials,
including
synthetic‐polymer‐based
their
recent
development
e‐skin
sensors,
robotics,
human–machine
interfaces
(HMIs).
Finally,
main
challenges
outlook
regarding
preparation
critically
discussed
near‐future
scenario,
which
expected
lead
next
generation
e‐skins.
