Acknowledgement
Page: iii-iii (1)
Author: Deepa Kodali and Vijaya Rangari
DOI: 10.2174/9789815196689123010002
Synergistic Effect of Bio-Nanocarbon Embedded Polymer Nanocomposite and its Applications
Page: 1-34 (34)
Author: Vandana Molahalli, Jasmine Joseph, Kiran Bijapur, Aman Sharma, Gowri Soman and Gurumurthy Hegde*
DOI: 10.2174/9789815196689123010004
PDF Price: $15
Abstract
For applications involving sustainable materials, bio-nanocarbon was
examined as a material to improve the properties of fiber-reinforced nano-biocomposite. A thorough investigation has been conducted using nano biocarbon as a
filler and reinforcing material. However, the composite's inferior mechanical, physical,
and thermal properties are a result of a poor fiber-matrix interface. As a result, in this
study, biocarbon nanoparticles were created and used as functional components to
enhance the properties of polymeric composite materials. To emphasize the scientific
and technological issues that need to be resolved in order to create artificial composites
with bio-inspired structures, recent studies of bio-inspired nano-carbon composites are
discussed in this study. These include the production techniques for resolving the nanocarbon dispersion problem and creating bio-inspired structures, as well as the
microstructure and composite characteristics characterization. In order to reveal natural
design principles and serve as a resource for future research, bio-inspired composites
and their applications are thoroughly examined and explained.
Biochar-thermoplastic Polymer Composites: Recent Advances and Perspectives
Page: 35-58 (24)
Author: Giulio Malucelli*
DOI: 10.2174/9789815196689123010005
PDF Price: $15
Abstract
To fulfill the current circular economy concept, several attempts to reuse and
valorize wastes and by-products coming from different sectors (such as the agri-food,
textile, and packaging industries, among others) are being carried out at least at a lab
scale by academics, despite the increasing interest that also involves the industrial
world. One of the up-to-date strategies to transform wastes and by-products into new
added-value systems refers to the production of biochar (BC), a carbonaceous solid
residue derived from the thermo-chemical conversion, under controlled conditions, of
wastes or, more generally, biomasses. Apart from its conventional uses (such as for soil
remediation, heat and power production, low-cost carbon sequestration, and as a
natural adsorbent, among others), BC is gaining a continuously increasing interest as a
multifunctional micro-filler for different thermoplastic and thermosetting polymer
matrices. Undoubtedly, the wide possibility of producing BC from different biomass
sources, wastes, and by-products offers an attractive prospect toward a circular bioeconomy with “zero waste”. When incorporated into a polymer at different loadings,
BC can provide thermal and electrical conductivity, EMI shielding features, enhanced
mechanical properties, and flame retardance as well. This chapter aims to summarize
the current achievements in the design, preparation, and characterization of
thermoplastic polymer/biochar composites, discussing the current limitations/
drawbacks, and providing the reader with some perspectives for the future.
Animal-Based Biochar Reinforced Polymer Composites
Page: 59-71 (13)
Author: Radhika Mandala*, B. Anjaneya Prasad and Suresh Akella
DOI: 10.2174/9789815196689123010006
PDF Price: $15
Abstract
Biomass-derived waste management has become an increasingly pressing
concern due to rising levels of environmental issues. As a result, interest has risen in
finding ways to turn biomass wastes into useful products. The conversion of biowaste
into biochar is one of the efficient and environmentally friendly methods of disposing
of biowaste. Developing polymer composites by reinforcing biochar as the filler
material is gaining popularity due to their affordability and exceptional thermal and
mechanical properties. Animal waste is one of the biomass wastes that can be
converted into biochar and can be used in various applications. This review work
aimed at synthesizing biochar from animal wastes, preparing polymer composites, and
analyzing the thermo-mechanical properties. This review also focuses on various
animal feedstocks for the synthesis of biocarbon and methods to fabricate polymer
composites. The biocarbon-induced polymer composites showed an improvement in
mechanical and thermal properties with varying percentages of loading.
Harnessing Agro-based Biomass for Sustainable Thermal Energy Storage with Biochar Polymer Nanocomposites
Page: 72-86 (15)
Author: Venkateswara Rao Kode*
DOI: 10.2174/9789815196689123010007
PDF Price: $15
Abstract
Food loss due to wastage is a severe issue for the entire world. Wastage
accounts for up to one-third of lost food output globally. Although there are various
ways to turn food waste into useful functional materials, landfilling is still a frequent
practice. This results in greenhouse gas emissions, which increase the already
significant greenhouse gas emissions linked to the agriculture sector. In this review, we
start by identifying multiple biomass sources and synthesis methods for biochar made
from biomass. This contains methods for the characterization of phase change polymer
nanocomposite materials impregnated with biochar. In order to compare the thermal
properties of phase change materials and gain an understanding of the various
biowastes, a comprehensive methodology was used.
The Application of Biocarbon Polymer Nanocomposites as Filaments in the FDM Process – A Short Review
Page: 87-97 (11)
Author: Singaravel Balasubramaniyan*, Niranjan Thiruchinapalli and Rutika Umesh Kankrej
DOI: 10.2174/9789815196689123010008
PDF Price: $15
Abstract
Fused Deposition Modeling (FDM) is a solid-based 3D printing process. It is
one of the additive manufacturing technologies that is used to create a threedimensional (3D) object using a CAD model. In the FDM process, raw material also
known as filament, is initially in the solid state. Nowadays, biocarbon-incorporated
polymer-based nanocomposite is used as a filament in the FDM process, due to the
enhanced strength of the base polymer. In this paper, a review of carbon extracted from
natural waste, such as tea powder, coffee grounds, egg shells, ocean plastic, coconut
shells, etc., is presented The extraction procedure of biocarbon is given in detail. The
results indicate that the strength enhancement of polymers can be achieved by
incorporation of derived carbon from industry as well as agriculture waste. In addition,
biocarbon-based polymer nanocomposite filaments in the FDM process can be
developed by reinforcing the polymer matrix with carbon nanoparticles. Future work of
this review process will explore the biobased carbon from various waste resources. The
application of biocarbon-based polymer nanocomposites for the 3D printing process is
highlighted.
Tensile Characteristics of FDM 3D Printed PBAT/PLA/Carbonaceous Biocomposites
Page: 98-114 (17)
Author: Gustavo F. Souza, Rene R. Oliveira, Janetty J.P. Barros, Fernando L. Almeida and Esperidiana A.B. Moura*
DOI: 10.2174/9789815196689123010009
PDF Price: $15
Abstract
The use of carbonaceous fillers in polymeric biocomposite materials has
been widely studied due to their potential to add better engineering properties to
biocomposites and expand their field of applications. Currently, due to the growing
global concerns over environmental pollution and climate change, carbonaceous fillers
derived from biomass are the preferred choice for production of the sustainable
biocomposite materials. Rice husk ash (RHA), an abundant and sustainable
carbonaceous filler obtained from the burn of rice husk in kilns of the processing rice
was incorporated into the PBAT/PLA blend. The influence of RHA loading on the
tensile properties of FDM-3D printed samples was investigated. Neat PBAT/PLA
filament and its biocomposite filaments with 2.5, 5.0 and 7.5 wt. % RHA were
prepared by the extrusion process. The filaments were characterized by FTIR, TG, and
SEM. FDM-3D printed specimens were subjected to tensile tests.
Biochar-Based Polymer Composites: A Pathway to Enhanced Electrical Conductivity
Page: 115-126 (12)
Author: Mahesh K. Pallikonda* and Joao A. Antonangelo
DOI: 10.2174/9789815196689123010010
PDF Price: $15
Abstract
In the past 20-25 years, biochar has been promoted as a valuable resource of
a carbon filler in polymer composites, sustainable agriculture, and environmental
quality protection given its improved porous structure and electrochemical properties in
comparison to other carbon-based materials. Recent works focusing on biochar and
biochar-based nanocomposites are highlighting such properties and are even enhanced
with nanotechnology. The higher porosity attributed to biochar is highlighted along
with its great electrochemical properties able to retain nutrients for longer and favors
their slow release. The use of biochar as a filler material to improve the electrical
conductivity properties of polymers and the emphasis on various parameters, such as
pyrolysis temperature, the type of feedstock, and compaction pressures on the electrical
conductivity of the resultant composites are discussed.
Coconut Shell Derived Carbon Reinforced Polymer Composite Films for Packaging Applications
Page: 127-140 (14)
Author: Gautam Chandrasekhar and Vijaya Rangari*
DOI: 10.2174/9789815196689123010011
PDF Price: $15
Abstract
With the advancement toward global sustainability, there is a widespread
demand for sustainable materials that can be used for various applications. Carbon has
gained much attention in the past few decades due to its scope of utilization in energy
and environment related applications. Biomass resources are considered a prominent
precursor for the synthesis of carbon-based materials due to their availability and
economic viability. In this study, high-quality graphitic carbon is synthesized from
Coconut Shell Powder (CSP) by pyrolysis and reinforced into a low-density
polyethylene (LDPE) matrix for fabricating films for packaging applications. A
custom-built high-temperature autogenic pressure reactor was used for conducting the
pyrolysis to synthesize carbon from the coconut shell powder and a blown film
extruder was used for fabricating composite films. For preparing the films, coconut
shell powder-derived carbon was added to the LDPE matrix at various weight percent
loadings of 0.25, 0.5, and 1 wt.%, respectively. Various analytical techniques such as
scanning electron microscopy, X-ray diffraction, Raman spectroscopy,
thermogravimetric analysis, tensile test, and differential scanning calorimetry were
used for studying the properties of carbon and LDPE/carbon composite films. Upon
adding carbon as fillers, there were significant improvements in the tensile and thermal
degradation properties of the polymer carbon composite films. Upon the incorporation
of carbon into the LDPE matrix, the crystallinity and tensile strength were found to
improve by a maximum of 29% and 13%, respectively.
Carbon Based Polymer Composites in Water Treatment and Filtration
Page: 141-149 (9)
Author: Sabina Yeasmin* and Soma Bose
DOI: 10.2174/9789815196689123010012
PDF Price: $15
Abstract
The world at large has acknowledged the importance of environmental
issues. The depletion of natural resources, such as drinking water, and the emission of
greenhouse gases that result in climatic change and the deterioration of human health,
are the primary concerns. As urban areas expand rapidly, they exert enormous strain on
nearby water supplies, leading to a global freshwater demand surge that is outpacing
population expansion. The development of polymer nanocomposites has contributed
significantly to the search for viable answers to pressing ecological concerns. Their
ability to eradicate pollutants, including gas emissions, heavy metals, and dyes in
wastewater has garnered researchers’ attention. In this overview, polymer
nanocomposites, as well as the composites reinforced with biocarbon that are used in
environmentally friendly ways, are discussed in detail. The adsorption mechanism and
applications of polymer nanocomposites for the removal of hazardous metal ions and
dyes were also studied.
Subject Index
Page: 150-154 (5)
Author: Deepa Kodali and Vijaya Rangari
DOI: 10.2174/9789815196689123010013
Introduction
This book explores cutting-edge biocarbon polymer composites. The book brings together nine edited chapters that explore the development, properties, and applications of these eco-friendly materials, highlighting their potential to transform industries and reduce the environmental impact of traditional polymers. Spanning a range of critical topics, this book begins with an introduction to biocarbon and polymer materials, providing a solid foundation. It then progresses into the latest research on biocarbon sources, processing techniques, and characterization methods. Subsequent chapters cover the mechanical, thermal, and electrical properties of biocarbon polymer composites, along with their applications in diverse industries such as automotive, construction, and packaging. Contributors highlight real-world case studies and examples to showcase the practical relevance of these materials. Readers will gain a comprehensive understanding of the science and technology behind biocarbon polymer composites, enabling them to make informed decisions in materials selection and development. In an era of increasing environmental consciousness, this book emphasizes the eco-friendly nature of biocarbon composites, offering sustainable alternatives to traditional plastics. Additionally, this book bridges the information gaps between different disciplines and it is intended for a wide range of readers, from materials scientists and engineers to environmentalists and industry policymakers.