Food Packaging: Advanced Materials, Technologies, and Innovations is a one-stop reference for packaging materials researchers working across various industries. With chapters written by leading international researchers from industry, academia, government, and private research institutions, this book offers a broad view of important developments in food packaging. Presents an extensive survey of food packaging materials and modern technologies Demonstrates the potential of various materials for use in demanding applications Discusses the use of polymers, composites, nanotechnology, hybrid materials, coatings, wood-based, and other materials in packaging Describes biodegradable packaging, antimicrobial studies, and environmental issues related to packaging materials Offers current status, trends, opportunities, and future directions Aimed at advanced students, research scholars, and professionals in food packaging development, this application-oriented book will help expand the reader’s knowledge of advanced materials and their use of innovation in food packaging.

Electrospinning is a versatile method to synthesize fibre materials. Electrospun Nanofibres: Materials, Methods, and Applications explores the technical aspects of electrospinning methods used to derive a wide range of functional fibre materials and their applications in various technical sectors. As electrospinning is a process that can be modified strategically to achieve different fibres of interest, this book covers the wide spectrum of electrospinning methodologies, such as coaxial, triaxial, emulsion, suspension, electrolyte and gas-assisted spinning processes. • Discusses a broad range of materials, including synthetic polymers, biodegradable polymers, metals and their oxides, hybrid materials, nonpolymers, and more. • Reviews different electrospinning methods and combined technologies. • Describes process-related parameters and their influence on material properties and performance. • Examines modeling of the electrospinning process. • Highlights applications across different industries. This book is aimed at researchers, professionals, and advanced students in materials science and engineering.

This book gives a comprehensive overview of bionanocomposites, a class of materials that consist of a biopolymer matrix which is embedded with nanoparticles and natural fibres as reinforcement to produce novel material and achieve superior physico-chemical and mechanical properties. The book looks into the synthesis of various forms of nanoparticles, the fabrication methods, and the characterization of bionanocomposites. It also includes topics related to the sustainability and life prediction of bionanocomposites such as biodegradability, recycling, and re-use. An important aspect in the designing of bionanocomposites includes computational modeling, and the suitability of the bionanocomposites in various applications is presented. This book appeals to students, researchers, and scientists looking to gain fundamental knowledge, know about recent advancements in the research on bionanocomposites and their applications.

Highlights the utilization of nanofillers. Investigates the moisture absorption and ageing on the physio-chemical, mechanical, thermal properties of the vinyl ester-based composites. Considers the influence of hybridization, fibre architecture, and fibre-ply orientation on the mechanical and thermal properties of vinyl ester-based biocomposites. Discusses the effects of the alkali treatment. Chapters are written by global experts to cover a diverse scope of industry applications for fibre-reinforced polymer composites.

Highlights the performance of epoxy-based biocomposites with reinforced with various natural fibres and plant resources. Investigates the behavior of hybrid biocomposites and biocomposites reinforced with various nanofillers. Evaluates the response of epoxy-based biocomposites exposed to moisture absorption, accelerated weathering, and hygrothermal aging. Discusses the static and dynamic properties, such as creep, fatigue, and free vibration properties. Chapters are written by global experts to cover a diverse scope of industry applications for fiber-reinforced polymer composites.

This book covers the topic of degradation phenomenon of natural fiber-based composites (NFC) under various aging conditions and proposes suitable solutions to improve the response of natural fiber-reinforced composite to aging conditions such as moisture, seawater, hygrothermal, and natural and accelerated weathering. The information provided by the book plays a vital role in the durability and shelf life of the composites as well as broadening the scope of outdoor application for natural fiber-based composites. The book will be appropriate for researchers and scientist who are interested in the application of natural fiber composites in various fields.

Fiber-reinforced polymer composites exhibit better damping characteristics than conventional metals due to the viscoelastic nature of the polymers. There has been a growing interest among research communities and industries in the use of natural fibers as reinforcements in structural and semi-structural applications, given their environmental advantages. Knowledge of the vibration and damping behavior of biocomposites is essential for engineers and scientists who work in the field of composite materials. Vibration and Damping Behavior of Biocomposites brings together the latest research developments in vibration and viscoelastic behavior of composites filled with different natural fibers. Features: Reviews the effect of various types of reinforcements on free vibration behavior Emphasizes aging effects, influence of compatibilizers, and hybrid fiber reinforcement Explores the influence of resin type on viscoelastic properties Covers the use of computational modeling to analyze dynamic behavior and viscoelastic properties Discusses viscoelastic damping characterization through dynamic mechanical analysis. This compilation will greatly benefit academics, researchers, advanced students, and practicing engineers in materials and mechanical engineering and related fields who work with biocomposites. Editors Dr. Senthil Muthu Kumar Thiagamani, Kalasalinagam Academy of Research and Education (KARE), India Dr. Md Enamul Hoque, Military Institute of Science and Technology (MIST), Bangladesh Dr. Senthilkumar Krishnasamy, King Mongkut's University of Technology North Bangkok KMUTNB, Thailand Dr. Chandrasekar Muthukumar, Hindustan Institute of Technology & Science (HITS), India Dr. Suchart Siengchin, King Mongkut's University of Technology North Bangkok KMUTNB, Thailand

A composite sandwich panel is a hybrid material made up of constituents such as a face sheet, a core, and adhesive film for bonding the face sheet and core together. Advances in materials have provided designers with several choices for developing sandwich structures with advanced functionalities. The selection of a material in the sandwich construction is based on the cost, availability, strength requirements, ease of manufacturing, machinability, and post-manufacturing process requirements. Sandwich Composites: Fabrication and Characterization provides insights into composite sandwich panels based on the material aspects, mechanical properties, defect characterization, and secondary processes after the fabrication, such as drilling and repair. FEATURES Outlines existing fabrication methods and various materials aspects Examines composite sandwich panels made of different face sheets and core materials Covers the response of composite sandwich panels to static and dynamic loads Describes parameters governing the drilling process and repair procedures Discusses the applications of composite sandwich panels in various fields Explores the role of 3D printing in the fabrication of composite sandwich panels Due to the wide scope of the topics covered, this book is suitable for researchers and scholars in the research and development of composite sandwich panels. This book can also be used as a reference by professionals and engineers interested in understanding the factors governing the material properties, material response, and the failure behavior under various mechanical loads.

Polyester-Based Biocomposites highlights the performance of polyester-based biocomposites reinforced with various natural fibres extracted from leaf, stem, fruit bunch, grass, wood material. It also addresses the characteristics of polyester-based biocomposites reinforced with rice husk fillers and various nanoparticles. The book explores the widespread applications of fibre-reinforced polymer composites ranging from the aerospace sector, automotive parts, construction and building materials, sports equipment, and household appliances. Investigating the advantages of natural fibres, such as superior damping characteristics, low density, biodegradability, abundant availability at low cost and non-abrasive to tooling, the book discusses what makes them a cost-effective alternative reinforcement material for composites in certain applications. The book serves as a useful reference for researchers, graduate students, and engineers in the field of polymer composites.

Discover the principles and applications of biocomposites with this comprehensive guide For decades, lightweight composites composed of synthetic fibers have found an enormous range of industrial applications, often replacing metals in various industrial processes because of their distinctive properties. However, these synthetic fibers produce considerable carbon dioxide emissions and are difficult to recycle, making them unsuited to renewable industry and the demands of a sustainable world. In recent years, polymer composites of natural fibers—called biocomposites—have been gaining popularity, presenting a superior alternative both ecologically and mechanically. Tribological Properties, Performance and Applications of Biocomposites provides a comprehensive overview of these natural fiber polymer composites and their properties as they behave in relate motion and interact with other substances. Drawing insights from both academic research and industry, it provides both theoretical insights and practical applications of biocomposite polymers. The result is an essential tool in updating industry with cutting-edge technology for a sustainable future. Tribological Properties, Performance and Applications of Biocomposites readers will also find: Detailed discussion of biocomposites as they interact with different matrices, nanoparticles, and more Applications for technologies in areas including dental, biomedical, and tissue engineering An editorial team with decades of combined experience in biocomposite research Tribological Properties, Performance and Applications of Biocomposites is ideal for materials scientists, chemists, and engineering scientists in both academia and industry.

Biocomposites for Industrial Applications: Construction, Biomedical, Transportation and Food Packaging reviews the properties and performance of these materials, with a focus on their intended applications. Sections cover their properties and performance, including processing conditions, structure and property relations. For biomedical applications, researchers need a broad understanding of conceptual design, physico-chemical properties, and cytotoxicity (orthopedic implants). As the usage of biocomposites has increased significantly over recent years, mainly due to the advantages these materials have when compared to synthetic composites, such as (i) renewability (ii) eco-friendly components, (iii) biodegradable aspects, and (iv) non-toxicity, this book provides a great update on the technology. These advantages will help to attract wider use in more lightweight-based applications such as (i) construction and building (ii) biomedical (iii) transportation (automotive, marine, and aerospace), and (iv) in food packaging.

This book gives a comprehensive overview of bionanocomposites, a class of materials that consist of a biopolymer matrix which is embedded with nanoparticles and natural fibres as reinforcement to produce novel material and achieve superior physico-chemical and mechanical properties. The book looks into the synthesis of various forms of nanoparticles, the fabrication methods, and the characterization of bionanocomposites. It also includes topics related to the sustainability and life prediction of bionanocomposites such as biodegradability, recycling, and re-use. An important aspect in the designing of bionanocomposites includes computational modeling, and the suitability of the bionanocomposites in various applications is presented. This book appeals to students, researchers, and scientists looking to gain fundamental knowledge, know about recent advancements in the research on bionanocomposites and their applications.

Food Packaging: Advanced Materials, Technologies, and Innovations is a one-stop reference for packaging materials researchers working across various industries. With chapters written by leading international researchers from industry, academia, government, and private research institutions, this book offers a broad view of important developments in food packaging. Presents an extensive survey of food packaging materials and modern technologies Demonstrates the potential of various materials for use in demanding applications Discusses the use of polymers, composites, nanotechnology, hybrid materials, coatings, wood-based, and other materials in packaging Describes biodegradable packaging, antimicrobial studies, and environmental issues related to packaging materials Offers current status, trends, opportunities, and future directions Aimed at advanced students, research scholars, and professionals in food packaging development, this application-oriented book will help expand the reader's knowledge of advanced materials and their use of innovation in food packaging.