Arbind Prasad – författare

Sustainable Packaging Strengthened by Biomass: Applications and Advancements explores the pivotal role of bioplastics in addressing packaging concerns within the food industry, enhancing delivery chains and streamlining waste management. Each chapter offers a detailed analysis, providing a thorough overview of present and future biodegradable materials. From untapped natural resources to bio-based materials like polyhydroxyalkanoate and polylactic acid, users will discover key components shaping the industry. The book also examines surface modification, biocomposites, and additives, emphasizing their role in adjusting biodegradability and properties, particularly in gas and moisture barriers.This is a must-read guide for those seeking a concise understanding of sustainable packaging and its transformative impact on the future.Examines bio-based materials as alternatives to petrochemicals for packaging applications, which is essential due to environmental impact and consumer responsibilityEvaluates the sustainability and recycling prospects of bio-based packaging materials and processingExplores the key benefits of materials and their functional strategies

This text provides an in-depth overview of sustainability in machining processes, challenges during machining of difficult-to-cut materials and different ways of green machining in achieving sustainability.It discusses important topics including green and sustainable machining, dry machining, textured cutting coated tools for machining, solid lubricants-based machining, gas-cooled machining, cryogenic cooling for intelligent machining, artificial neural network for machining, big data based machining, and hybrid intelligent machining. This book- Covers advances in sustainable machining such as gas-cooled machining, near dry machining, and minimum quantity lubrication. Explores use of big data, machine learning and artificial intelligence for machining processes. Provides case studies and experimental design as well as results with analysis focusing on achieving sustainability. Discusses artificial intelligence and machine learning based machining processes. Cover the latest applications of sustainable manufacturing for a better understanding of the concepts. The text is primarily written for senior undergraduate, graduate students, and researchers in the fields of mechanical, manufacturing, industrial, production engineering and materials science.

"Biodegradable Composites for Packaging Applications" describes design, processing, and manufacturing of advanced biodegradable composites in packaging industry applications. It covers fundamentals of biodegradable polymers followed by introduction to biodegradable materials for food packaging industry and its processing mechanisms. Pertinent applications are explained across different chapters including intelligent packaging, applied technologies, degradation problems and its impact on environment and associated challenges. FeaturesCovers biodegradable composites and targeted applications in packaging for industrial applications.Includes exhaustive processing and characterizations of biodegradable composites. Discusses innovative commodities packaging applications. Reviews advanced integrated design and fabrication problems for conductive and sensors applications. Explores various properties and functionalities through extensive theoretical and experimental modeling.This volume is aimed at researchers and graduate students in sustainable materials, composite technology, biodegradable plastics, and food technology and engineering.

"Biodegradable Composites for Packaging Applications" describes design, processing, and manufacturing of advanced biodegradable composites in packaging industry applications. It covers fundamentals of biodegradable polymers followed by introduction to biodegradable materials for food packaging industry and its processing mechanisms. Pertinent applications are explained across different chapters including intelligent packaging, applied technologies, degradation problems and its impact on environment and associated challenges. FeaturesCovers biodegradable composites and targeted applications in packaging for industrial applications.Includes exhaustive processing and characterizations of biodegradable composites. Discusses innovative commodities packaging applications. Reviews advanced integrated design and fabrication problems for conductive and sensors applications. Explores various properties and functionalities through extensive theoretical and experimental modeling.This volume is aimed at researchers and graduate students in sustainable materials, composite technology, biodegradable plastics, and food technology and engineering.

This text provides an in-depth overview of sustainability in machining processes, challenges during machining of difficult-to-cut materials and different ways of green machining in achieving sustainability.It discusses important topics including green and sustainable machining, dry machining, textured cutting coated tools for machining, solid lubricants-based machining, gas-cooled machining, cryogenic cooling for intelligent machining, artificial neural network for machining, big data based machining, and hybrid intelligent machining. This book- Covers advances in sustainable machining such as gas-cooled machining, near dry machining, and minimum quantity lubrication. Explores use of big data, machine learning and artificial intelligence for machining processes. Provides case studies and experimental design as well as results with analysis focusing on achieving sustainability. Discusses artificial intelligence and machine learning based machining processes. Cover the latest applications of sustainable manufacturing for a better understanding of the concepts. The text is primarily written for senior undergraduate, graduate students, and researchers in the fields of mechanical, manufacturing, industrial, production engineering and materials science.

The text discusses both theoretical and technological aspects of the Industry 4.0–based manufacturing processes. It covers important topics such as additive manufacturing, laser-based manufacturing processes, electromagnetic welding and joining processes, green manufacturing processes, and friction welding processes. Illustrates sustainable manufacturing aspects in robotics and aerospace industries. Showcases additive manufacturing processes with a focus on innovation and automation. Covers environment-friendly manufacturing processes resulting in zero waste and conserves natural resources. Synergizes exploration related to the various properties and functionalities through extensive theoretical and experimental modeling. Discusses impact welding for joining of dissimilar materials.The text discusses the recent manufacturing techniques and methodologies such as impact welding for joining of dissimilar materials. It further covers techniques such as additive manufacturing and electromagnetic manu- facturing, resulting in minimum or negligible waste. The text elaborates important topics such as friction stir welding energy consumption analysis, and industry waste recycling for sustainable development. It will serve as an ideal reference text for senior undergraduate, graduate students, and researchers in the fields including mechanical engineering, aerospace engineering, manufacturing engineering, and production engineering.

The text discusses both theoretical and technological aspects of the Industry 4.0–based manufacturing processes. It covers important topics such as additive manufacturing, laser-based manufacturing processes, electromagnetic welding and joining processes, green manufacturing processes, and friction welding processes. Illustrates sustainable manufacturing aspects in robotics and aerospace industries. Showcases additive manufacturing processes with a focus on innovation and automation. Covers environment-friendly manufacturing processes resulting in zero waste and conserves natural resources. Synergizes exploration related to the various properties and functionalities through extensive theoretical and experimental modeling. Discusses impact welding for joining of dissimilar materials.The text discusses the recent manufacturing techniques and methodologies such as impact welding for joining of dissimilar materials. It further covers techniques such as additive manufacturing and electromagnetic manu- facturing, resulting in minimum or negligible waste. The text elaborates important topics such as friction stir welding energy consumption analysis, and industry waste recycling for sustainable development. It will serve as an ideal reference text for senior undergraduate, graduate students, and researchers in the fields including mechanical engineering, aerospace engineering, manufacturing engineering, and production engineering.

The text comprehensively highlights the key issues surrounding the implementation of waste-to-energy systems, such as site selection, regulatory aspects and financial, and economic implications. It further discusses environmental aspects of food waste to energy conversion, microbial fuel cells (MFCs) for waste recycling and energy production, and valorization of algal blooms and their residues into renewable energy.This book:Discusses the environmental impact of waste-to-energy and sustainable waste-to-energy technologies in a comprehensive manner.Presents life cycle assessment studies and perspective solutions in waste-to-energy sectors.Covers applications of smart materials in thermal energy storage systems.Explains thermo-chemical technologies for recycling plastic waste for energy production and recovery of valuable products.Illustrates biorefineries and case studies for sustainable waste valorization.It is primarily written for senior undergraduate nad graduate students, and academic researchers in the fields of mechanical engineering, environmental engineering, energy studies, production engineering, industrial engineering, and manufacturing engineering.

The text begins by discussing the processing and characterization of nano-manufactured resorbable bionanocomposites and presents the latest advances in carbon-based polymer nanocomposite materials for sensing applications. It further presents different characterization techniques such as scanning electron, transmission electron, atomic force microscopy, and powder X-ray diffraction for the identification of bionanocomposites.This book:• Introduces nano-manufactured processed composites for biomedical application, processing, and characterization of bionanocomposites.• Presents biobased nano-manufactured processed composites for imaging, tissue repairing, and drug-delivery applications.• Explains future trends of nano-manufactured composites in 3D bio-implants and fluorescent bioimaging.• Highlights the challenges and perspectives of polymeric nano-manufactured composites for biomedical applications.• Covers multifunctional nano-manufactured bio-composites, and advances in polymeric membranes for healthcare applications.It is primarily written for senior undergraduates, graduate students, and academic researchers in the fields of manufacturing engineering, biomedical engineering, materials science and engineering, mechanical engineering, and production engineering.

The text begins by discussing the processing and characterization of nano-manufactured resorbable bionanocomposites and presents the latest advances in carbon-based polymer nanocomposite materials for sensing applications. It further presents different characterization techniques such as scanning electron, transmission electron, atomic force microscopy, and powder X-ray diffraction for the identification of bionanocomposites.This book:• Introduces nano-manufactured processed composites for biomedical application, processing, and characterization of bionanocomposites.• Presents biobased nano-manufactured processed composites for imaging, tissue repairing, and drug-delivery applications.• Explains future trends of nano-manufactured composites in 3D bio-implants and fluorescent bioimaging.• Highlights the challenges and perspectives of polymeric nano-manufactured composites for biomedical applications.• Covers multifunctional nano-manufactured bio-composites, and advances in polymeric membranes for healthcare applications.It is primarily written for senior undergraduates, graduate students, and academic researchers in the fields of manufacturing engineering, biomedical engineering, materials science and engineering, mechanical engineering, and production engineering.

The text comprehensively highlights the key issues surrounding the implementation of waste-to-energy systems, such as site selection, regulatory aspects and financial, and economic implications. It further discusses environmental aspects of food waste to energy conversion, microbial fuel cells (MFCs) for waste recycling and energy production, and valorization of algal blooms and their residues into renewable energy.This book:Discusses the environmental impact of waste-to-energy and sustainable waste-to-energy technologies in a comprehensive manner.Presents life cycle assessment studies and perspective solutions in waste-to-energy sectors.Covers applications of smart materials in thermal energy storage systems.Explains thermo-chemical technologies for recycling plastic waste for energy production and recovery of valuable products.Illustrates biorefineries and case studies for sustainable waste valorization.It is primarily written for senior undergraduate nad graduate students, and academic researchers in the fields of mechanical engineering, environmental engineering, energy studies, production engineering, industrial engineering, and manufacturing engineering.

This book is essential for anyone interested in understanding and implementing sustainable transportation practices, as it provides comprehensive insights into the challenges, advancements, and policies related to sustainable mobility. Sustainable transportation refers to any means of transportation that is “green” and has a low impact on the environment. The goal of sustainable transportation is to balance our current and future needs. As per the United Nations Brundtland Commission (WCED, 1987), sustainable mobility can be defined as “mobility that satisfies the needs of present generations without compromising future generations”, but in the modern era, we are compromising the needs of the next generation in terms of pollution, depletion of fossil fuels, global warming, poor air quality, and hazardous gases. The three main pillars of sustainability, economics, environment, and social issues, are crushed by modern development, so there is a need to shift from traditional means of transportation to sustainable transportation. Under the vision of sustainable mobility, better infrastructure and services will be provided to support the movement of goods and people. This outcome will be achieved only if four goals are pursued simultaneously: developing the right policy, building awareness, developing intelligent transportation, and creating green vehicles. Sustainable Mobility: Policies, Challenges and Advancements will discuss transitions from conventional to sustainable mobility, infrastructure development challenges in this transition period, new vehicle policies, and the latest autonomous vehicles for intelligent transportation. The main highlights of the book are energy efficient technologies for transportation, accessibility and safety of the transport system, environmental footprint, health impacts, economic development, and social growth. Sustainable mobility is essential to economic and social development. The environmental impacts of transport can be reduced by reducing the weight of vehicles, creating sustainable styles of driving, reducing the friction of tires, encouraging electric and hybrid vehicles, improving the walking and cycling environment in cities, and enhancing the role of public transport, especially electric vehicles. Going green and sustainable is not only beneficial for the company, but it also maximizes the benefits of an environmental focus in the long term.

ADVANCED MATERIALS and MANUFACTURING TECHNIQUES for BIOMEDICAL APPLICATIONSThe book provides essential knowledge for the synthesis of biomedical products, development, nanomaterial properties, fabrication processes, and design techniques for different applications, as well as process design and optimization.In origin, biomaterials can come from nature or be synthesized in the laboratory with a variety of approaches that use metals, polymers, ceramic, or composite materials. They are often used or adapted for various biomedical applications. Biomaterials are commonly used in scaffolds, orthopedic, wound healing, fracture fixation, surgical sutures, artificial organ developments, pins and screws to stabilize fractures, surgical mesh, breast implants, artificial ligaments and tendons, and drug delivery systems.The sixteen chapters in Advanced Materials and Manufacturing Techniques in Biomedical Applications cover the synthesis, processing, design, manufacturing, and characterization of advanced materials; self-healing, bioinspired, nature-resourced, nanobiomaterials for biomedical applications; and manufacturing techniques such as rapid prototyping, additive manufacturing, etc.AudienceThe book is for engineers, technologists, and researchers working in the area of biomedical engineering and manufacturing techniques. It is also appropriate for upper-level undergraduate and graduate students.

Unlock the potential of the intersection of additive manufacturing and biomedicine with this essential guide, which provides a comprehensive look at the applications, challenges, and industrial advancements of biomaterials for industrial processes. The sustainability of any process lies in how eco-friendly and economical its products are. Bio-based materials of different origins are emerging as a sustainable option for raw materials for different products with diverse applications. The book highlights the fabrication of implants, scaffolds, and biomedical devices based on naturally sourced biobased materials, with coverage that includes: Emerging biobased composites for orthopedic, soft tissue, and hard tissue engineering; An in-depth study of the latest emerging manufacturing process and resorbable materials for biomedical applications; Biological and degradation studies, along with challenges associated with resorbable implants; Special chapters on artificial organ development through additive manufacturing and their processing; Challenges in additive manufacturing related to processing and cost-effectiveness of resorbable polymeric implants. Readers will find the volume: Focuses on the practical application of 3D printing in medicine, covering areas like implants, prosthetics, drug delivery, and tissue engineering; Explores the crucial aspects of materials science and process optimization necessary for successful biomedical additive manufacturing;Addresses the growing trend of personalized medicine enabled by patient-specific 3D-printed scaffolds and implants;Provides detailed studies on chitosan, PCL, alginate, and cellulose biomaterials as feedstock for additive manufacturing using composites;Discusses the challenges and industrial advancements driving the adoption of additive manufacturing in the biomedical sector.Audience Academics, practitioners, polymer scientists, biomedical and mechanical engineers, materials scientists, and researchers working in the areas of additive manufacturing in biomedical applications.

Biomaterials have become an integral part of medicine today, helping in healing and restoring functionality in people with injury or disease, especially for bone implants and drug delivery systems. This has led to the development of polymers that are biocompatible, biodegradable, and/or resorbable. This new book presents the latest resesasrch on bio-based composites, processing, and characterization for drug delivery and fixation devices.Key features:Highlights the latest processing and characterization of the bioabsorbable composite materialsOutlines a broad range of different areas such as wound healing, craniofacial, maxillofacial, drug carriers, and fixation devices for orthopedic fixationsDiscusses advanced techniques for the development of composites and biopolymer-based compositesPresents the latest developments in synthesis, preparation, characterization, mechanical evaluation, and future challenges of composite applications in drug delivery and fixation devices

The sustainability of any process lies in the eco-friendly and economical production of products for applications. Bio-based materials are emerging as raw materials for different products and applications. The book covers cellulose, chitosan, silk, collagen and gelatin bio-based materials. It describes their use in biomedical applications, such as orthopaedic implant, drug delivery, tissue culture, biosensor and engineering applications such as fuel cells, energy storage and packaging. It concludes with the use of bio-based materials as precursors for biorefinery, biolubricants, membranes and adsorbents.

This book will consist of the development, processing, and manufacturing of high-performance metallic biomaterials in healthcare and biomedical applications in context with surface modification and coating of implants. Bioresorbable metallic composites along with high-performance metallic materials and their processing, and characterizations will be the central theme of the book. Effectively, the variety of fifteen chapters presented in the book will be quite interesting and up-to-date with the scope of future research work. This has the potential to be valuable to researchers in material engineering disciplines, biomedical engineering, and also to clinical professions. The background information and the latest literature review provided in each chapter will be an in-depth analysis of the topic covered in the chapter.

The convergence of biology, engineering, and digital intelligence has ushered in a transformative era for regenerative medicine. At the heart of this revolution lies 3D bio printing, a technology that has evolved from a futuristic concept into a robust scientific discipline capable of fabricating complex, functional living tissues. This edited volume, "Bio printing: Artificial Intelligence, Biomaterials, Cells, and Tissue," serves as a comprehensive roadmap for this interdisciplinary landscape. It is designed to bridge the gap between fundamental research and clinical application by exploring the four critical pillars (Artificial Intelligence, Biomaterials, Cells and Tissue Engineering) that define the modern bio printing workflow.

This book covers the latest research and relevant case studies about emerging resorbable materials, their synthesis, characterization, and applications in various domains.