Book Volume 1
Preface
Page: i-i (1)
Author: Subhendu Bhandari, Prashant Gupta and Ayan Dey
DOI: 10.2174/9789815124811123010001
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Foreword
Page: ii-ii (1)
Author: Debabrata Chakrabarty
DOI: 10.2174/9789815124811123010002
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Polymer Composites for Construction Applications
Page: 1-19 (19)
Author: Dinesh Rathod, Madhuri N. Mangulkar and Bhagwan Ghanshamji Toksha*
DOI: 10.2174/9789815124811123010004
PDF Price: $15
Abstract
Polymer composite concrete (PCC) nowadays plays a major role in the
construction industry. PCC is a valuable element in the development of sustainable
construction materials. The polymers and classical concrete blends offer newer
properties and applications. A polymeric action in the field of admixtures provides
insight into the development of highly performing modified mineral concrete and
mortars. The influence of various polymers on the properties of concrete is variable due
to the polymeric chain reactions. The optimization of properties such as crack
resistance, permeability, and durability with the addition of polymer is required. The
present work reviews the types, performances, and applications of PCC to improve
various properties of concrete in both fresh and hardened states as they have shown a
strong potential from technical, economical, and design points of view.
Polymer Composites as Packaging Materials
Page: 20-57 (38)
Author: Amandeep Singh and Sovan Lal Banerjee*
DOI: 10.2174/9789815124811123010005
PDF Price: $15
Abstract
This chapter aims to obtain a better understanding of the role of polymer
nanocomposites in different packaging applications such as food packaging, electronic
packaging, and industrial packaging. Dispersion of nanoparticles (NPs) in the
packaging materials improves the properties like mechanical strength and modulus,
water resistance, gas permeability, etc. In addition, bioactive agents in the packaging
materials impart interesting smart phenomena like antimicrobial, and antifouling
properties. Generally, petroleum fuel-based thermoplastic polymers are conventionally
used in primary and secondary packaging. Some of the widely used polymeric
packaging materials consist of polyethylene terephthalate (PET), high-density
polyethylene (HDPE), polyvinyl chloride (PVC), low-density polyethylene (LDPE),
polypropylene (PP), and polystyrene (PS). However, as the consequence of the harmful
impacts of fossil fuel-based packaging materials on humans, animals, and the
environment has become understandable, more and more emphasis has been shifted to
biopolymers (cellulose, protein, marine prokaryotes, etc.) and their nanocomposites.
Bio-based or bio-originated polymers or biopolymers are eco-friendly, non-hazardous
to living beings as well as to the environment, biodegradable, abundant, and a better
alternative to depletable fossil fuel-based materials. Biopolymer-based nanocomposites
advocate all desirable aspects of a packaging material to be sustainable, reliable, and
environmentally friendly. In addition, the nature-inspired active and intelligent/smart
packaging materials are economical and their contribution to reviving the circular
economy is prominent.
Polymer Composites in Tissue Engineering
Page: 58-86 (29)
Author: Togam Ringu, Sampad Ghosh and Nabakumar Pramanik*
DOI: 10.2174/9789815124811123010006
PDF Price: $15
Abstract
A composite is a multiphase material made of layers of stacked phase i.e., a
matrix, an interface and a reinforced phase. The matrix phase is the main constituent of
a composite. The interface binds the matrix and the reinforced phase, whereas, the
latter provides strength to the material. Based on the matrix and the reinforced phase, it
may be classified into various types such as fibers, particles, polymers, ceramics and
metals. Polymer composite is a sub-type of composite having a polymer matrix and
different reinforced materials. Due to its biocompatible nature, it is widely used in the
field of biomedical applications. Many manufacturing methods are used in composites,
but some of the commonly used manufacturing techniques include hand lay-up,
reinforced reaction injection molding (RRIM), centrifugal casting, etc. High strength,
and ductility with lightweight, cytocompatibility, and non-toxicity are some of the
properties due to which composite materials are widely used in various industries such
as automobile, aerospace, sports equipment, and tissue engineering. In tissue
engineering (TE), a biomaterial called a scaffold, is developed that evolves into a
functional tissue. Enhanced cell proliferation, cell adhesion and cell viability are
observed with the composite-developed scaffold. Scaffold is fabricated using two types
of composites; natural and synthetic composites. The applications of polymer
composites at the bioengineering level are of great interest nowadays. This chapter
intends to study various physicochemical properties of polymer composites including
their bioengineering/tissue engineering applications elaborately. The study
investigating the physicochemical properties and bioengineering/tissue engineering
applications of polymer composites may bestow valuable insight into the potential of
polymer composites in modern science.
Polymer Composites for Energy Storage Application
Page: 87-122 (36)
Author: Rupesh Rohan*
DOI: 10.2174/9789815124811123010007
PDF Price: $15
Abstract
The chapter discusses the role and application of polymers (polymers and
composites) in energy storage devices. Lithium-ion batteries and supercapacitors are
the two main energy storage intermittents. The chapter underscores the utilization of
polymers in various roles in these devices and their effect on performance, in addition
to related future aspects and expectations.
Polymer Composite Membrane for Microbial Fuel Cell Application
Page: 123-145 (23)
Author: Kalpana Sharma, Anusha Vempaty, Barun Kumar, Shweta Rai, Vaibhav Raj, Deepak Jadhav and Soumya Pandit*
DOI: 10.2174/9789815124811123010008
PDF Price: $15
Abstract
Energy production is a demanded process in today’s world. Some processes
might generate pollutants and other undesirable particulates and toxic chemicals. One
such eco-friendly and efficient method for generating electricity and energy can be
through fuel cells with the utilization of microbes (bacteria). Such a method can be
termed Microbial Fuel Cells (MFCs). It is a bio-electrochemical system. It uses
bacteria and their biochemical processes for generating an electric current, along with
oxygen which is a high-energy oxidant. MFCs imitate the bacterial interactions that are
found in the nature. Being a cell, it requires electrodes, substrates, and electrolytic
solutions. To improve the efficiency of the MFC, we need to separate the anode and
cathode into two compartments and the respective reactions taking place. Membranes
play a crucial role in achieving it. A membrane not only divides the anode from the
cathode but also prevents the entry of oxygen into the anode chamber. The most
important function of a membrane is to allow the selective transfer of ions across the
two electrode chambers. Membranes can be diaphragms or separators. Porous
membranes are commercially used ones usually made of different effective polymer
materials. Other important membranes can be semi-permeable and ion-exchange
membranes. This chapter mainly reviews the various membranes and the materials
used in their structures that have the potential to increase the MFC performance. It also
focuses on the different transport processes across the membranes, along with a brief of
advances in this technology and future scope.
Polymer Composites for Sensor Applications
Page: 146-164 (19)
Author: Arti Rushi, Kunal Datta and Bhagwan Ghanshamji Toksha*
DOI: 10.2174/9789815124811123010009
PDF Price: $15
Abstract
Polymers play a major role in sensor research nowadays. Specifically, when
the electrical modality of sensing is concentrated then conducting polymers is found to
be highly useful. They have been explored for the development of sensors to cope with
advanced modern-day requirements. There is a huge demand for sensors in detecting
and assessing environmental dynamics, harmful working conditions, food poisoning,
and water contaminations, and diagnostic purposes. The recent pandemic, the COVID-19 outburst all over the world, ascertained the urgency of research in the direction of
designing and developing biosensors enabling distinction among the diseases and
enabling medical professionals to take faster clinical decisions. The conventional
approaches in environment pollutant detection techniques have no universally accepted
code of conduct. Moreover, there are various experimental drawbacks of poor
calibration, tedious sample preparation, blank determination, and lengthy time-consuming procedure. The composites involving conducting polymers and CNTs bring
in unique multifunctional features. The motive of the present work is to review various
latest developments in conducting polymer composite-based sensors.
Polymer Composites for Automotive Applications
Page: 165-196 (32)
Author: Naveen Veeramani, Prosenjit Ghosh, Tushar Kanti Das and Narayan Chandra Das*
DOI: 10.2174/9789815124811123010010
PDF Price: $15
Abstract
The last couple of decades have witnessed exceptional advancements in
automotives; and the use of polymer composites (PCs) in making different automotive
parts has emerged as an integral part of the advancement. Fiber-reinforced PCs offer
weight benefits to automotives, thus enhancing fuel economy. Moreover, these
composites can be engineered for versatile applications, e.g., interior and exterior body
parts. Ease of manufacturing is another advantage of PCs, although several major
technical considerations still need to address before engineering these composites for
wide-scale acceptance in various automotive applications, especially for exterior body
parts. However, PCs are a new class of materials, and developing state-of-the-art
manufacturing technology may enhance the comfort and security of modern vehicles.
This chapter outlines the utility and recent advances in PCs for various automotive
applications. In addition, quality assurance and the advantages of PCs are also given.
The potential of PCs for future perspectives is also discussed.
Subject Index
Page: 197-201 (5)
Author: Subhendu Bhandari, Prashant Gupta and Ayan Dey
DOI: 10.2174/9789815124811123010011
PDF Price: $15
Introduction
This volume is a comprehensive guide to the industrial use of polymer composites. Edited contributions demonstrate the application of these materials for different industrial sectors. The book covers the benefits, future potential, and manufacturing techniques of different types of polymers. Contributors also address challenges in using nanopolymers in these industries. Readers will find valuable insights into the current demand and supply of polymer composites and future scope for research and development in this field of polymer science. The volume presents seven chapters, each exploring a different application of polymer composites. Chapter 1 discusses the use of polymer additives for improving classical concrete and the workability and durability of polymer composite concrete. Chapter 2 explores the use of polymer nanocomposites in packaging, including smart/intelligent packaging, modified atmosphere packaging, and vacuum packaging. Chapter 3 delves into the use of polymer composites in tissue engineering, including manufacturing techniques and various applications. Chapter 4 explores energy storage applications for polymer composites, while Chapter 5 discusses their use in microbial fuel cells. Chapter 6 explores the use of carbon nanotubes in polymer composite gas sensors. Finally, Chapter 7 discusses the use of polymer composites in automotive applications. This is an ideal reference for researchers, scientists, engineers, and professionals in the fields of materials science, polymer science, engineering, and nanotechnology. The content is also suitable for graduate and postgraduate students studying industrial manufacturing.