Microplastics in the Marine Environment: Challenges and the Shift Towards Sustainable Plastics and Plasticizers
Journal of Hazardous Materials,
Journal Year:
2025,
Volume and Issue:
unknown, P. 137945 - 137945
Published: March 1, 2025
Language: Английский
Development of Toughened Poly (lactic acid) by Melt Blending with Poly (butylene adipate-co-terephthalate) Using Epoxidized Castor Oil as a Compatibilizer for Biomedical Applications
K. P. Ajeya,
No information about this author
Yelaware Puttaswamy Naveen,
No information about this author
K. T. Vishnu
No information about this author
et al.
Deleted Journal,
Journal Year:
2025,
Volume and Issue:
unknown
Published: March 11, 2025
Language: Английский
Impact of Infill Density on the Mechanical Properties and Design of 3d-Printed Structures
N. Tamiloli,
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K. Elangovan,
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J. Venkatesan
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et al.
Published: Jan. 1, 2025
Language: Английский
Homogeneous biopolymer films based on polybutylene adipate terephthalate for packaging applications
Angkana Kralin,
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Anchasa Kamjaikittikul,
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Pisuth Lertvilai
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et al.
Journal of Materials Science,
Journal Year:
2025,
Volume and Issue:
unknown
Published: May 2, 2025
Language: Английский
Thermal Decomposition of Bio-Based Plastic Materials
Inés Oliver,
No information about this author
Juan A. Conesa,
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Andrés Fullana
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et al.
Molecules,
Journal Year:
2024,
Volume and Issue:
29(13), P. 3195 - 3195
Published: July 5, 2024
This
research
delves
into
a
detailed
exploration
of
the
thermal
decomposition
behavior
bio-based
polymers,
specifically
thermoplastic
starch
(TPS)
and
polylactic
acid
(PLA),
under
varying
heating
rates
in
nitrogen
atmosphere.
study
employs
thermogravimetry
(TG)
to
investigate,
providing
comprehensive
insights
stability
these
eco-friendly
polymers.
In
particular,
TPS
kinetic
model
is
examined,
encompassing
three
distinct
fractions.
contrast,
PLA
exhibits
simplified
requiring
only
fraction
described
by
zero-order
model.
The
involves
systematic
investigation
individual
contributions
key
components
within
TPS,
including
starch,
glycerin,
polyvinyl
alcohol
(PVA).
analysis
contributes
understanding
degradation
process
PLA,
enabling
optimization
processing
conditions
prediction
material
across
environments.
Furthermore,
incorporation
different
sources
calcium
carbonate
additives
enhances
our
polymer’s
stability,
offering
potential
applications
diverse
industries.
Language: Английский
Innovative Poly(Lactic Acid) Blends: Exploring the Impact of the Diverse Chemical Architectures from Itaconic Acid
Polymers,
Journal Year:
2024,
Volume and Issue:
16(19), P. 2780 - 2780
Published: Sept. 30, 2024
Environment-friendly
polymer
blends
of
poly(lactic
acid)
(PLA)
and
itaconic
acid
(IA),
poly(itaconic
(PIA),
acid)-co-poly(methyl
itaconate)
(Cop-IA),
net-poly(itaconic
acid)-ν-triethylene
glycol
dimethacrylate
(Net-IA)
were
performed
via
melt
blending.
The
compositions
studied
0.1,
1,
3,
10
wt%
the
diverse
chemical
architectures.
research
aims
to
study
understand
effect
IA
its
different
architectures
on
mechanical,
rheological,
thermal
properties
PLA.
PLA/IA,
PLA/PIA,
PLA/Cop-IA,
PLA/Net-IA
characterized
by
dynamic
mechanical
analysis,
rotational
rheometer
(RR),
thermogravimetric
differential
scanning
calorimetry,
X-ray
diffraction,
electron
microscopy.
complex
viscosity,
storage
module,
loss
module
for
RR
observed
in
following
order:
PLA/Net-IA,
PLA/PIA
>
PLA
PLA/IA.
Thermal
stability
improved
with
increasing
concentrations
Cop-IA
Net-IA.
In
same
way,
enhanced.
addition,
micrographs
illustrated
formation
fibrillar
structures
all
blends.
crystallinity
degree
displayed
higher
values
that
contain
Net-IA
than
PIA.
Therefore,
can
influence
these
properties,
which
have
potential
applications
disposable
food
packing.
Language: Английский