Satyaranjan Bairagi – författare

Textile-Based Piezoelectric Nanogenerators: Advances and Perspectives reviews materials, fabrication methods, and applications of piezoelectric textile materials for smart wearable systems and portable electronic technologies. In the book, current achievements in piezoelectric nanogenerators are summarized, and applications of the textile-based piezoelectric nanogenerators in the fields of sensing, structural health monitoring, and energy harvesting are discussed. Drawbacks and opportunities in these areas are also investigated, making this reference suitable for materials scientists and engineers in academia and R&D.Introduces textile-based piezoelectric materials used for energy harvesting from mechanical energy wasteCovers fabrication of piezoelectric nanogenerators in conventional textiles for the development of next-generation wearable energy harvestersProvides systematic and comprehensive coverage of the topic and highlights current and potential applications of textile-based piezoelectric nanogenerators for further investigation

Textile- and Fiber-Based Triboelectric Nanogenerators: Advances and Perspectives presents the latest developments in triboelectric nanogenerators, covering current achievements and applications, as well as potential future applications. The book identifies the key drawbacks to these devices and then proposes solutions in a systematic way. It presents a guide for material scientists, electrical and chemical engineers, and industry practitioners on the current state-of-the- art of this multidisciplinary research area, while also opening up important new avenues of research for the industry to further develop smart textile-based energy harvesting devices.Readers will find comprehensive coverage of all types of textile- and fiber-based triboelectric nanogenerators for application in wearable technologies and self-powered electronics. It also outlines the unique advantages of triboelectric nanogenerators, their design considerations and guidelines, and the key challenges in translating them from the lab into real-world applications, with a particular focus on applications in the fields of sensing, structural health monitoring, and energy harvesting.

Introduces textile-based triboelectric materials used for harvesting energy from mechanical energy wasteCovers fabrication of triboelectric nanogenerators in conventional textiles for the development of next-generation wearable energy harvestersProvides systematic and comprehensive coverage of textile-based triboelectric nanogenerators and highlights current and potential applications

Biopolymer-Based Composites for Energy Storage and Generation covers the properties and performance of various biopolymers, examining their potential applications in batteries, supercapacitors, and solar cells, alongside considerations of their environmental impact, economic benefits, and associated challenges and limitations. Chapters discuss the fundamentals of biopolymers used in the energy field, cover their essential properties and performance, and feature specific applications, including batteries, supercapacitors, solar cells, portable electronics, electric vehicles, and grid energy storage. The book concludes by discussing the role of biopolymers in energy harvesting and generation, energy efficiency, and conservation.It critically examines challenges and limitations, considering both environmental impact and economic benefits. Research advancements and future directions are also discussed, making this a valuable resource for researchers and professionals interested in the application of sustainable materials in the energy sector.Explores the properties and performance of various types of biopolymers and biocomposites used in energy generation and storage technologiesDescribes diverse applications of biopolymer-based composites in energy storage and generation, ranging from portable electronics and electric vehicles to grid storageFeatures case studies and techno-economic aspects associated with the utilization of biopolymer-based composites for energy storage and generation

Nanotechnology in Textile Dyeing and Printing explores the latest advancements in nanotechnology and its application in creating innovative, functional textiles with advanced coloration properties. It discusses the future potential of nanotechnology in textile dyeing and printing, examining its impact on the textile industry. Additionally, it addresses ethical and environmental considerations associated with the use of advanced technology in textile production. The book starts by providing an overview of the fundamentals of nanotechnology pertinent to the textile dyeing and printing. It then features various types of nano-based dyes and pigments, including those based on nanoparticles, quantum dots, and other advanced materials currently in development. The exploration extends to how these nano-based dyes and pigments are employed to create new, advanced coloration effects in textiles. Examples from different areas, such as fashion, interior design, and technical textiles, are included. This book serves as an essential guide for those seeking to understand the cutting-edge technology shaping the future of textile dyeing and printing.Presents a detailed examination of the various types of nano-based dyes and pigments currently in development, including those based on nanoparticles, quantum dots, and other advanced materialsAddresses ethical and environmental considerations associated with the use of advanced technology in textile productionServes as a valuable resource for researchers and professionals in the textile industry looking to stay current on the latest advancements in nanotechnology and its application in textile dyeing and printing

Functional Nanotextiles: Processing, Properties, and Applications targets the underlying principles, state-of-the-art processing techniques, unique properties, and myriad applications of nanotextiles. Beyond the technical and academic facets, the book highlights the broader implications of nanotextiles, such as their environmental impacts, ethical considerations, and potential to reshape industries. In an era where sustainability, technological advancements, and multifunctionality are paramount, understanding functionalized nanotextiles becomes crucial. This book not only charts the current landscape but also speculates on the future trajectory of the field, making it a timely and essential resource.For stakeholders ranging from academic researchers to industry leaders, the book offers both a deep dive into specifics and a panoramic view of the broader ecosystem, ensuring its relevance in shaping the future of textiles, wearable technologies, and beyond.Explores the integration of nanotechnology into textiles, enhancing their performance with specialized functionalities like moisture-wicking and antimicrobial propertiesPresents collaborations across fields such as materials science, chemistry, and biology, thus driving innovation in nanotextiles and expanding their applicationsDetails methods of incorporating nanomaterials into textiles, highlighting their unique properties and impacts on performance and durabilityExamines the integration of electronic components into fabrics, enabling functions such as health monitoring and interactive fashionDiscusses the design and development of garments and accessories that incorporate advanced materials and technologies for enhanced functionality and user experience

Piezoelectric Composite Materials: Theory, Design and Applications provides a detailed overview of the latest advances in this important research field. Comprehensive in its coverage, the book offers a detailed review of the theoretical foundations, practical design considerations, and wide-ranging applications of these materials. This book will be an essential reference resource for academic and industrial researchers, materials scientists and engineers, manufacturers, industrial R&D, and other professionals who are working on the development and use of piezoelectric composite materials for a broad range of different applications.Covers, in detail, the fundamentals, properties, performance, and current and future potential applications of piezoelectric composite materialsDiscusses design and fabrication methodsContains practical case study examples of applications in sensors, actuators, health monitoring and energy harvesting devicesAnalyzes environmental impacts, economic benefits, challenges, limitations, future perspectives, and the circular economy

Power small devices more efficiently and practically with these essential materials Piezoelectric energy harvesting is an increasingly widely-deployed technique to generate electricity from mechanical energy. Reliability, ease of use, and cleanliness make piezoelectric energy harvesting in small electronic devices a potentially valuable alternative to the practical challenges and waste production of disposable or even reusable batteries. However, piezoelectric materials have their own challenges, advantages, and limitations, and choosing between them is a difficult engineering problem in itself; hybrid piezoelectric materials, which can be used to compensate the weaknesses of individual piezoelectric materials (like ceramic or polymer), are the emerging solution. Hybrid Materials for Piezoelectric Energy Harvesting and Conversion offers a systematic analysis of these hybrid piezoelectric materials and their applications. Each hybrid piezoelectric material is analyzed for its fundamentals, structural requirements, and applications, and the result is a significant contribution to materials science and electronic engineering. Hybrid Materials for Piezoelectric Energy Harvesting and Conversion readers will also find: Comprehensive coverage of piezoelectric materials to provide the best fit for any set of engineering needs Detailed discussion of inorganic, organic, and hybrid piezoelectric materials Surface modification of piezoelectric filler in composite based piezoelectric materials Importance of semiconductive and conductive materials in enhancing piezoelectric response of hybrid piezoelectric materials In depth analysis of bio-based hybrid piezoelectric materials Hybrid Materials for Piezoelectric Energy Harvesting and Conversion is ideal for researchers in materials sciences, polymers, textiles, green and renewable energy, and all related fields.