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Nanopapers: From Nanochemistry and Nanomanufacturing to Advanced Applications gives a comprehensive overview of the emerging technology of nanopapers. Exploring the latest developments on nanopapers in nanomaterials chemistry and nanomanufacturing technologies, this book outlines the unique properties of nanopapers and their advanced applications. Nanopapers are thin sheets or films made of nanomaterials such as carbon nanotubes, carbon nanofibers, nanoclays, cellulose nanofibrils, and graphene nanoplatelets. Noticeably, nanopapers allow highly concentrated nanoparticles to be tightly packed in a thin film to reach unique properties such as very high electrical and thermal conductivities, very low diffusivity, and strong corrosion resistance that are shared by conventional polymer nanocomposites. This book presents a concise introduction to nanopapers, covering concepts, terminology and applications. It outlines both current applications and future possibilities, and will be of great use to nanochemistry and nanomanufacturing researchers and engineers who want to learn more about how nanopapers can be applied. - Outlines the main uses of nanopapers, showing readers how this emerging technology should best be applied - Shows how the unique properties of nanopapers make them adaptable for use in a wide range of applications - Explores methods for the nanomanufacture of nanopapers
The recent explosion of interdisciplinary research has fragmented the knowledge base surrounding renewable polymers. The Chemistry of Bio-based Polymers, 2nd edition brings together, in one volume, the research and work of Professor Johannes Fink, focusing on biopolymers that can be synthesized from renewable polymers. After introducing general aspects of the field, the book's subsequent chapters examine the chemistry of biodegradable polymeric types sorted by their chemical compounds, including the synthesis of low molecular compounds. Various categories of biopolymers are detailed including vinyl-based polymers, acid and lactone polymers, ester and amide polymers, carbohydrate-related polymers and others. Procedures for the preparation of biopolymers and biodegradable nanocomposites are arranged by chemical methods and in vitro biological methods, with discussion of the issue of "plastics from bacteria." The factors influencing the degradation and biodegradation of polymers used in food packaging, exposed to various environments, are detailed at length. The book covers the medical applications of bio-based polymers, concentrating on controlled drug delivery, temporary prostheses, and scaffolds for tissue engineering. Professor Fink also addresses renewable resources for fabricating biofuels and argues for localized biorefineries, as biomass feedstocks are more efficiently handled locally.
Plant Biomass Application: Materials, Modification and Characterization focuses on the unique properties associated with plant biomass, from their biodegradable, non toxic, and safe for handling characteristics to their potential in developing sustainable, climate protecting products. Plant biomass has found many applications in the fields of biomedical, food, packaging, electronics, automotive, sensors, and textile industry, however there are very few books dealing in depth with materials derived from plant biomass for versatile application fields.This book covers all aspects of plant biomass materials opportunities with focus on the value-added product generated from plant biomass such as polymers, composites, transportation fuels, chemical intermediates/bulk chemicals, or sources of heat and generated power. The conversion of plant biomass into materials product such as plastics, fabrics, and carpets and specialty chemicals, presents exciting possibilities for replacing traditionally used fossil fuels. There are higher value, and more attractive, uses for for plant biomass use than just as fuel. Meanwhile, most agriculture, forestry, and food wastes contain ligno-cellulosic resource creating a vast and diverse resource generating system for plant biomass.Plant Biomass Materials provides and in-depth discussion of the materials derived from plant biomass and their current and potential future applications. Leading researchers from industries, academics, government and private research institutions across the globe have provided their insights, making it an important reference for researchers and academics seeking to maximize plant biomass potential. - Presents basic concepts, methods, technical concepts, literature review, and detailed application in particular fields for plant biomass materials - Focuses on the processing techniques for different biomass - Describes, in detail, processing methods, value-added products, and their applications in various fields like agriculture and food industry, energy, catalysis, and bio-medicinal applications
Paper Based Sensors, Volume 89, the latest release in this comprehensive series that gathers the most important issues relating to the design and application of these cost-effective devices used in many industries, including health and environment diagnostics, safety and security, chemistry, optics, electrochemistry, nanoscience and nanotechnologies, presents the latest updates in the field. Chapters in this new release include Exploring paper as a substrate for electrochemical micro-devices, Paper-based sensors for application in biological compound detection, Printed paper-based (bio)sensors: design, fabrication and applications, Paper-based electrochemical sensing devices, Multifarious aspects of electrochemical paper-based (bio)sensors, Paper Based Biosensors for Clinical and Biomedical Applications, and more. - Provides updates on the latest design in paper-based sensors using various nano and micromaterials - Includes optical/electrical-based detection modes integrated within paper-based platforms - Covers applications of paper-based platforms in diagnostics and other industries
Nanocellulose Based Composites for Electronics presents recent developments in the synthesis and applications of nanocellulose composites in electronics, highlighting applications in various technologies. Chapters covers new trends and challenges in a wide range of electronic applications and devices. Significant properties, safety, sustainability, and environmental impacts of the electronic devices are included, along with the challenges of using nanocellulose-based composites in electronics. This book is an important reference for materials scientists and engineers configuring and designing processes for the synthesis and device fabrication of nanocellulose composites in electronics. - Explores how to utilize nanocellulose fibers and nano-crystalline cellulose substances to synthesize materials with designed functionalities - Outlines the major production processes for nanocellulous composites - Discusses the major challenges that need to be surmounted in order to effectively use nanocellulous composites for electronics
The discipline of mycology is a fascinating one. It has a major influence on the nutrition, health and environmental safety of mankind. Cultivation of edible and non-edible mushrooms for nutrition, pharmaceuticals, biopolymers and biocomposites will open up new avenues in research as well as the more profitable utilization of agricultural residues. Cultivation and of domesticated and wild mushrooms poses a challenge to fulfill the needs of human/animal nutrition and utilization of agrowastes tangibly. Cultivation of ectomycorrhizal fungi benefits nutrition as well as plant protection. Macrofungi are the major source of several metabolites of nutritional, health, agricultural and industrial significance (e.g., antioxidants, antimicrobials and pigments). Macrofungal bio composites provide alternatives to the use of animal-derived or plant-derived products (e.g., nanopapers, leather and packaging materials). They serve a dual role in providing nutrition and pharmaceuticals (nutraceuticals) to humans as well as livestock. Macrofungi interact with insects symbiotically (e.g., Termitomyces with termites) and provide delicious nutraceutical product. They also control insects by infecting and producing pharmaceutically and metabolite-rich products (e.g., Cordyceps attacks insects). Macrofungi have a strong potential to control pathogens like nematodes in soil (bioremediation). They are also useful as biofertilizers to meet the needs of plant nutrition. The book outlines current advances in macrofungal technology. It highlights different facets of macrofungal cultivation, bioactive compounds, biocomposites, nutraceuticals, benefits with interaction with insects, application as biofertilizers and ecosystem services like bioremediation.
This book provides a detailed description of metal-complex functionalized carbon allotrope forms, including classic (such as graphite), rare (such as M- or T-carbon), and nanoforms (such as carbon nanotubes, nanodiamonds, etc.). Filling a void in the nanotechnology literature, the book presents chapters generalizing the synthesis, structure, properties, and applications of all known carbon allotropes. Metal-complex composites of carbons are described, along with several examples of their preparation and characterization, soluble metal-complex carbon composites, cost-benefit data, metal complexes as precursors of carbon allotropes, and applications. A lab manual on the synthesis and characterization of carbon allotropes and their metal-complex composites is included. Provides a complete description of all carbon allotropes, both classic and rare, as well as carbon nanostructures and their metal-complex composites; Contains a laboratory manual of experiments on the synthesis and characterization of metal-complex carbon composites; Discusses applications in diverse fields, such as catalysis on supporting materials, water treatment, sensors, drug delivery, and devices.
This handbook comprehensively reviews different nanomaterials and modern electrochemical approaches used in the point-of-care analysis of biomolecules. It describes the importance, significance, and application of various kinds of smart nanomaterials and their integration with modern electrochemical techniques for the point-of-care diagnosis of biologically important biomolecules. The interaction between bio-systems and nanomaterials have been discussed in this book using advanced electrochemical methods and characterizing techniques. It describes the combination of classical and modern methodologies for the synthesis of metal nanoparticles/nanoclusters and modern electrochemical techniques for the early-stage detection and point-of-care diagnosis of cancer and other infectious disease such as SARS, influenza, tuberculosis (TB), and hepatitis. Finally, the book provides an accessible and readable summary of the use of nanomaterial for understanding the electrochemical reaction taking place at nano-bio interfaces in electrochemical biomolecular detection and analysis. The book bridges the gap and strengthens the relationship between electrochemists, material scientists, and biomolecular scientists who are directly or indirectly associated with the field of such point-of-care diagnostics. ​
Since its advent, nanotechnologies are considered key enabling technologies that take advantage of a wide array of nanomaterials (NMs) for biomedical and industrial applications generating significant societal and economic benefits. However, such innovation increases human exposure to these substances through inhalation, ingestion or dermal contact raising public health concerns. Furthermore, the NMs’ specific physicochemical properties, that confer them unique beneficial characteristics, can also elicit nano-bio interactions leading to toxicity and concerns for public health. In addition, such properties can be affected by the surrounding matrix, particularly when incorporated in complex matrices such as food products, leading to secondary features potentially more relevant than primary characteristics for determining their toxicological outcome. These nano specific issues raise the question of whether the NMs may produce adverse outcomes that are not accounted for when using conventional toxicological approaches to assess their safety. Such uncertainties about the safety of NMs for human health and the environment may hamper a faster and more widespread exploration of their potentials. In response, the NMs definition has evolved, and nanotoxicology has developed towards new and more integrative approach methods to support regulatory and policy actions. This book provides a perspective on recent developments in the synthesis, application, and characterization of NMs and the related nanotechnologies, focusing on nanotoxicology for their accurate safety assessment early in the product development stage. The use of complex in vitro models, including multicellular systems and organoids, and “omics-based” approaches, such as transcriptomics or epigenomics, have greatly contributed to an in-depth understanding of the cellular and molecular mechanisms behind some NMs toxicity. Such mechanistic knowledge is equally addressed in this book and has set the basis for a predictive nanotoxicology approach building on adverse outcome pathways. In addition, considering the knowledge provided by the above-mentioned approaches, insights into risk assessment, standardization, and regulation of NMs are also included. Incorporating adequate nanosafety assessment early in the life-cycle of NMs will allow the implementation of the safe and sustainable-by-design paradigm enabling safety to keep pace with innovation. Chapters 10 and 15 are available open access under a Creative Commons Attribution 4.0 International License via link.springer.com.
Polymer-based advanced functional materials are one of most sought after products of this global high performance material demand as polymer-based materials guarantee both processing ease and mechanical flexibilities. This volume provides a comprehensive and updated review of major innovations in the field of polymer-based advanced functional materials which focuses on constructive knowledge on advanced multifunctional materials and their resultant techno-commercial applications. The contents aim at restricting the coverage to energy and environment related applications as the said two are the most emerging application domains of polymer-based advanced functional materials. It highlights the cutting-edge and recent research findings of polymer based advanced functional materials in energy and environment sectors wherein each chapter focuses on a specific energy and environment related application of polymer-based advanced functional materials, their preparation technique, nature enhancement achieved and allied factors. This volume would be of great interest to researchers, academicians and professionals, involved in polymers, chemistry, energy and environmental research, and other allied domains.