Advanced Materials,
Journal Year:
2024,
Volume and Issue:
unknown
Published: Dec. 11, 2024
Biomolecule
isolation
is
a
crucial
process
in
diverse
biomedical
and
biochemical
applications,
including
diagnostics,
therapeutics,
research,
manufacturing.
Recently,
MXenes,
novel
class
of
two-dimensional
nanomaterials,
have
emerged
as
promising
adsorbents
for
this
purpose
due
to
their
unique
physicochemical
properties.
These
biocompatible
antibacterial
nanomaterials
feature
high
aspect
ratio,
excellent
conductivity,
versatile
surface
chemistry.
This
timely
review
explores
the
potential
MXenes
isolating
wide
range
biomolecules,
such
proteins,
nucleic
acids,
small
molecules,
while
highlighting
key
future
research
trends
innovative
applications
poised
transform
field.
provides
an
in-depth
discussion
various
synthesis
methods
functionalization
techniques
that
enhance
specificity
efficiency
biomolecule
isolation.
In
addition,
mechanisms
by
which
interact
with
biomolecules
are
elucidated,
offering
insights
into
selective
adsorption
customized
separation
capabilities.
also
addresses
recent
advancements,
identifies
existing
challenges,
examines
emerging
may
drive
next
wave
innovation
rapidly
evolving
area.
Advanced Materials Interfaces,
Journal Year:
2024,
Volume and Issue:
unknown
Published: Sept. 30, 2024
Abstract
A
promising
flexible
photodetector
based
on
hybrid
nanocomposites
of
2D
MXene
and
In
2
O
3
nanoparticles
(NPs)
has
been
developed,
demonstrating
excellent
ultraviolet
(UV)
light
responsivity.
this
work,
‐decorated
nanosheets
(In
MX)
are
synthesized
via
a
simple
one‐step
sonochemical
method
using
ultrasonication,
rapidly
producing
the
composites
in
short
time.
The
material
shows
efficacy
across
broadband
wavelengths
(UV,
Vis,
NIR).
Notably,
MX
exhibits
responsivity
(
R
)
121.6
W
−1
specific
detectivity
D
*)
106.4
×
10¹⁰
Jones
UV
range,
confirming
enhanced
electrical
properties
feasibility
low‐voltage
detection
with
tau
plots.
Additionally,
optical
characteristics
remain
unchanged
after
bending
device
up
to
10,000
times
radius
6.0
mm,
highlighting
its
suitability
for
optoelectronic
applications.
Overall,
study
introduces
novel
approach
synthesis
provides
valuable
insights
into
development
photodetectors
these
materials.
With
the
rapid
advancement
of
wearable
technology,
multifunctional
sensors
have
garnered
significant
attention
due
to
their
potential
applications
in
environmental
monitoring,
health
diagnostics,
and
human−machine
interaction.
Despite
promise,
challenges,
such
as
limited
flexibility,
insufficient
sensitivity,
complex
production
processes,
hindered
practical
deployment.
This
study
presents
fabrication
a
flexible
sensor
based
on
PU-supported
Ti3C2Tx/TiO2/PPy
yarns
for
both
ammonia
(NH3)
gas
sensing
human
motion
detection.
Key
innovations
include
incorporation
polypyrrole
(PPy)
into
Ti3C2Tx
MXene
structure
optimization
titanium
dioxide
(TiO2)
content
through
varying
hydrothermal
times,
which
significantly
enhance
performance.
The
demonstrates
exceptional
sensitivity
selectivity
toward
NH3,
with
response
recovery
times.
Additionally,
composite
exhibit
excellent
mechanical
flexibility
durability,
maintaining
stable
performance
under
repeated
stretching
bending
cycles.
In
detection,
shows
high
reliable
monitoring
various
physical
activities,
making
it
highly
suitable
electronics.
These
features
ensure
sensor's
applicability
diverse
settings,
promoting
safety
environments
exposure
enhancing
interactions
accurate
monitoring.
Advanced Materials,
Journal Year:
2024,
Volume and Issue:
unknown
Published: Dec. 11, 2024
Biomolecule
isolation
is
a
crucial
process
in
diverse
biomedical
and
biochemical
applications,
including
diagnostics,
therapeutics,
research,
manufacturing.
Recently,
MXenes,
novel
class
of
two-dimensional
nanomaterials,
have
emerged
as
promising
adsorbents
for
this
purpose
due
to
their
unique
physicochemical
properties.
These
biocompatible
antibacterial
nanomaterials
feature
high
aspect
ratio,
excellent
conductivity,
versatile
surface
chemistry.
This
timely
review
explores
the
potential
MXenes
isolating
wide
range
biomolecules,
such
proteins,
nucleic
acids,
small
molecules,
while
highlighting
key
future
research
trends
innovative
applications
poised
transform
field.
provides
an
in-depth
discussion
various
synthesis
methods
functionalization
techniques
that
enhance
specificity
efficiency
biomolecule
isolation.
In
addition,
mechanisms
by
which
interact
with
biomolecules
are
elucidated,
offering
insights
into
selective
adsorption
customized
separation
capabilities.
also
addresses
recent
advancements,
identifies
existing
challenges,
examines
emerging
may
drive
next
wave
innovation
rapidly
evolving
area.
