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Handbook of Composites from Renewable Materials, Polymeric Composites

Name: Handbook of Composites from Renewable Materials, Polymeric Composites
Author: Vijay Kumar Thakur, Manju Kumari Thakur, Michael R. Kessler, Vijay Kumar Thakur, Manju Kumari Thakur, Michael R. Kessler

Vijay Kumar Thakur, Manju Kumari Thakur, Michael R. Kessler, Vijay Kumar Thakur, Manju Kumari Thakur, Michael R. Kessler

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eBook - ePub

Handbook of Composites from Renewable Materials, Polymeric Composites

Vijay Kumar Thakur, Manju Kumari Thakur, Michael R. Kessler, Vijay Kumar Thakur, Manju Kumari Thakur, Michael R. Kessler

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This unique multidisciplinary 8-volume set focuses on the emerging issues concerning synthesis, characterization, design, manufacturing and various other aspects of composite materials from renewable materials and provides a shared platform for both researcher and industry.

The Handbook of Composites from Renewable Materials comprises a set of 8 individual volumes that brings an interdisciplinary perspective to accomplish a more detailed understanding of the interplay between the synthesis, structure, characterization, processing, applications and performance of these advanced materials. The Handbook comprises 169 chapters from world renowned experts covering a multitude of natural polymers/ reinforcement/ fillers and biodegradable materials.

Volume 6 is solely focused on the " Polymeric Composites ". Some of the important topics include but not limited to: Keratin as renewable material for developing polymer composites; natural and synthetic matrices; hydrogels in tissue engineering; smart hydrogels: application in bioethanol production; principle renewable biopolymers; application of hydrogel biocomposites for multiple drug delivery; nontoxic holographic materials; bioplasticizer-epoxidized vegetable oils-based poly (lactic acid) blends and nanocomposites; preparation, characterization and adsorption properties of poly (DMAEA) – cross-linked starch gel copolymer in wastewater treatments; study of chitosan cross-linking hydrogels for absorption of antifungal drugs using molecular modelling; pharmaceutical delivery systems composed of chitosan; eco-friendly polymers for food packaging; influence of surface modification on the thermal stability and percentage of crystallinity of natural abaca fiber; influence of the use of natural fibers in composite materials assessed on a life cycle perspective; plant polysaccharides-blended ionotropically-gelled alginate multiple-unit systems for sustained drug release; vegetable oil based polymer composites; applications of chitosan derivatives in wastewater treatment; novel lignin-based materials as a products for various applications; biopolymers from renewable resources and thermoplastic starch matrix as polymer units of multi-component polymer systems for advanced applications; chitosan composites: preparation and applications in removing water pollutants and recent advancements in biopolymer composites for addressing environmental issues.

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Información

Editorial

Wiley-Scrivener

Año

2017

ISBN

9781119224433

Edición

Categoría

Tecnologia e ingegneria

Categoría

Ingegneria chimica e biochimica

Chapter 1
Keratin as Renewable Material to Develop Polymer Composites: Natural and Synthetic Matrices

Flores-Hernandez C.G., Murillo-Segovia B., Martinez-Hernandez A.L.^* and Velasco-Santos C

Division of Graduate Studies and Research, Technological Institute of Querétaro, Querétaro, Mexico

^*Corresponding author: [email protected]

Abstract

Keratin is a structural fibrous protein, considered as the main constituent of wool, hair, horns, feathers and other outer coverings of mammals, reptiles and birds. This protein represents an inexhaustible source of non-contaminant materials for possible diverse applications. In the last decade the use of keratin in different forms to elaborate polymer composites has opened a novel and outstanding research field. Ongoing research have been developed keratin materials from diverse sources as reinforcements. These have been in the form of fibers, particles, nanoparticles or powder, among others. Thus, this chapter reviews different studies related to the use of keratin materials obtained from feathers, wool, hair and other renewable sources in order to reinforce polymer matrices. The properties obtained in these polymer composites are discussed separately depending on the nature of the matrix, natural or synthetic. The possible applications and the future of these kinds of composites are also discussed.

Keywords: Keratin, natural fiber, polymer composites, biodegradable polymer

1.1 Introduction

Biocomposites can be obtained from plant or living beings (natural/biofiber) and crop-derived plastics (bio-plastic). Actually, these are considered novel materials, still in development during the beginning of the twenty-first century (Singha & Thakur, 2009a–c; 2010a–c). The study of these materials started as an answer to a growing environmental threat and as attempt to supply solutions for the coming problem about petroleum supply (Mohanty et al., 2002; Thakur et al., 2016). It was reported that since the 1960s the demand for non-continuous components of composites has been growing incessantly. For example, in 1967, in the United States, necessities for fillers by the plastic production were around 525,000 tons, whereas in 1998, 1,925,000 tons were required by the same industry (Eckert, 1999). By this century, in 2000 the US market for natural composites exceeded $150 million (Mohanty et al., 2002), but for 2010, the projected requirement for fillers for the United States plastic production was to 3.85 billion kilograms, from which 0.31 billion kilograms (8%) were expected to be bio-based fibers (Farsi, 2012).

Natural fibers are the support to develop high performing fully biodegradable eco or green composites (Thakur et al., 2013a-e). Natural fibers are considered as biodegradable and environmentally friendly, mainly due to their plant-based cellulosic or lignocellulosic fibers. Much research is being undertaken of these as natural prospects for reinforcing (or filling) polymers to make them less aggressive towards the environment (Netravali & Chabba, 2003). In agreement with Thakur et al., (2014), one of the most successful emerging areas of interest in polymer engineering and materials science is precisely related to the proper application of raw natural fibers as an essential element towards achievement of new low-cost green composites.

In reality, many scientists have found an interesting research field by using plant-based fibers due to their ready availability. However, different prospects exist if high-strength protein fibers are taken into account. For example, keratin can be obtained from chicken feathers, wool, hair and horns. Keratin, a non-food protein, is an abundant biopolymer, and because of its animal origin, it is a renewable and low-priced feedstock. It is also assessed that worldwide there are some million tons per year of material-based keratin disposed in landfills that comes from non-used residues of wools, hairs, feathers, horns and nails (Bertini et al., 2013).

This chapter reviews the latest advancements in the field of composites with synthetic and natural matrices using keratin as reinforcement. The first section begins with a brief description of the structural characteristics of keratin. Subsequently, different natural materials that contain keratin are compared. In the second section, composites with synthetic matrices and different sources of keratin as reinforcement are detailed. The methods, techniques and properties are described for these composites. The last part discusses composites with natural matrices reinforced with keratin from different natural sources.

It is worthy of mention that there are many matrix systems that have been reinforced with keratin materials; therefore these novel composites are versatile to different applications depending on the desired properties. However, important criteria in the synthesis procedures must be carefully observed, since natural characteristics of keratin represent certain processing restrictions. Examples of these criteria could be: processing methods, morphological structures of keratin reinforcements, quantity of keratin used to reinforce matrices, among others. Thus, this review aims to describe the development of different polymeric composites using natural and synthetic matrices and applying renewable keratin reinforcements obtained from different natural sources.

1.2 Keratin

Keratin is present in almost all animals that have a backbone; this protein is the product of the keratinization process, which occurs because the skin cells die and accumulate in the surface layer. This protein can be considered as soft or hard, according to the diverse mechanism of biosynthesis (Meyers et al., 2008). Mammals have diverse tissues formed by hard keratin (skin, hair, wool, nail, claw, quill, horn, hoof and whale baleen), all of which are sophisticated epidermal appendages, differentiated not only by their external ...