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The unique nanoscale properties of renewable biomaterials presentvaluable opportunities in the field of nanoscience and technology.Lignocellulosic biomass is an important industrial resource whichcan be used for the production of highly efficient andenvironmentally sustainable nanomaterials. The Nanoscience and Technology of Renewable Biomaterialspresents the latest advances in biomass nanotechnology, includingleading research from academia and industry, as well as a futurevision for the nanotechnology of forest products. Topics covered include: A fundamental review of the relationship betweennanotechnology and lignocellulosic biomass Characterization methods for biomass on the nanometerscale Cellulose, hemicelluloses and lignin as nanoscopicbiomaterials-physical features, chemical properties and potentialnanoproducts Nanoscale surface engineering Renewable materials as scaffolds for tissue engineering Nanoscopically-controlled drug delivery This book will be a valuable resource for chemists, chemicalengineers, bioscience researchers and materials scientists who areinterested in harnessing the nanotechnological features ofrenewable biomaterials.
Composites from Renewable and Sustainable Materials consists of 16 chapters written by international subject matter experts investigating the characteristic and current application of materials from renewable and sustainable sources. The reader will develop a deeper understanding about the concepts related to renewable materials, biomaterials, natural fibers, biodegradable composites, starch, and recycled materials. This book will serve as the starting point for materials science researchers, engineers, and technologists from the diverse backgrounds in physics, chemistry, biology, materials science, and engineering who want to know and better understand the fundamental aspects and current applications of renewable and sustainable materials in several applications.
This book focuses on the use of nanotechnology and nanomaterials in the production of biofuels. It describes the current production technologies for different biofuels and their limitations for commercialization, and discusses in detail how nanomaterials could reduce biofuel production costs. After an introduction to biofuels, the book examines biofuels economics and policy; biofuel production processes – advances and limitations; nanotechnology and its energy applications; nanotechnology in biohydrogen production – for cellulases, in algal fuel, and in bioethanol/biobutanol and biodiesel production. It is a valuable resource for researchers and engineers.
Nanomaterials: Application in Biofuels and Bioenergy Production Systems looks at how biofuels and bioenergy can be part of the "sustainable" solution to the worlds energy problems. By addressing bioenergy products compared to their fossil energy counterparts, covering research and development in biofuels applied with nanomaterials this book analyzes the future trends and how biofuels and bioenergy can contribute to its optimization. Starting from fundamentals up to synthesis, characterization and applications of nanomaterials in biofuels and bioenergy production systems, the chapters include the procedures needed for introducing nanomaterials in these specific sectors along with the benefits derived from their applications. Including the hazards and environmental effects of nanomaterials in bioenergy applications, sustainability issues and a techno-economic analysis of the topic, this book provides researchers in bioscience, energy & environment and bioengineering with an up to date look at the full life cycle assessment of nanomaterials in bioenergy. - Provides a one stop solution manual for applications of nanomaterials in bioenergy and biofuels - Includes biofuel applications with compatible global application case studies - Addresses the demand for environmental and techno-economic analysis of nanomaterials applications
Biomass as Renewable Raw Material to Obtain Bioproducts of High-tech Value examines the use of biomass as a raw material, including terrestrial and aquatic sources to obtain extracts (e.g. polyphenols), biofuels, and/or intermediates (furfural, levulinates) through chemical and biochemical processes. The book also covers the production of natural polymers using biomass and the biosynthetic process, cellulose modified by biochemical and chemical methods, and other biochemicals that can be used in the synthesis of various pharmaceuticals. Featuring case studies, discussions of sustainability, and nanomedical, biomedical, and pharmaceutical applications, Biomass as Renewable Raw Material to Obtain Bioproducts of High-tech Value is a crucial resource for biotechnologists, biochemical engineers, biochemists, microbiologists, and research students in these areas, as well as entrepreneurs, policy makers, stakeholders, and politicians. - Reviews biomass resources and compounds with bioactive properties - Describes chemical and biochemical processes for creating biofuels from biomass - Outlines production of polysaccharides and cellulose derivatives - Features applications in the fields of medicine and pharmacy
Nanotechnology in Paper and Wood Engineering: Fundamentals, Challenges and Applications describes recent advances made in the use of nanotechnology in the paper and pulp industry. Various types of nano-additives commonly used in the paper industry for modification of raw material to enhance final products are included, with other sections covering the imaging applications of nano-papers and nano-woods in pharmaceuticals, biocatalysis, photocatalysis and energy storage. This book is an important reference source for materials scientists and engineers who are looking to understand how nanotechnology is being used to create more efficient manufacturing processes in for the paper and wood industries. - Provides information on nano-paper production and its applications - Explains the major synthesis techniques and design concepts of cellulosic or wooden nanomaterials for industrial applications - Assesses the major challenges of creating nanotechnology-based manufacturing systems for wood and paper engineering
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.
The potential future fluctuations in energy security and potential climate change impacts require an emphasis on clean and renewable energies to safeguard the environment as well as economic livelihoods. The current recalcitrant nature of biomass processing has led researchers to find the most suitable technique for its depolymerization, as well as various strategies to pretreat the biomass which include physical, thermochemical, and biochemical methods and a combination of these. Biomass Energy for Sustainable Development examines how optimal biomass utilization can reduce forest management costs, help mitigate climate change, reduce risks to life and property, and help provide a secure, competitive energy source into the future. Features: Provides a comprehensive review of biomass energy and focuses on in-depth understanding of various strategies to pretreat biomass including physical, chemical, and biological Explores multidisciplinary, novel approaches including AI for furthering the understanding and generation of models, theories, and processes in the field of bioenergy Covers the sustainable development goals for bioenergy, including the related concepts of bioeconomy and the potential environmental impact from reliance on bioenergy
A unique feature of this book is its focus on nanotechnological solutions for the production of bioenergy and biofuels. Coverage includes topics such as nanobiotechnology, microalgae, biofuel cells, biomass pretreatment, and biomass conversion. An international team of experts also addresses the need to precisely characterize nanoparticles and the role of catalysts. The range of topics addressed, together with a chapter on risk management, make this book a highly useful resource for a broad readership including physicists, chemists, microbiologists, biotechnologists, food technologists, agricultural engineers, and nanotechnologists.
This volume focuses on technological advances relevant to establishing biofuels as a viable alternative to fossil fuels by overcoming current limitations. The progressive depletion of fossil fuels due to their large-scale utilization and their environmental consequences, notably global warming, increase the need for sustainable and cleaner energy options. Renewable biofuels – like biohydrogen, biomethane, biogas, ethanol and butenol – represent attractive energy sources to meet the growing global demand, thanks to sustainable and cost-efficient production approaches based on cellulosic biomass. Currently, the commercialization of these technologies is hindered by technical and economic limitations, such as biomass complexity and pre-treatment, enzyme hydrolysis, production efficiency as well as storage and cost. As such, this book presents economically viable and sustainable approaches to improve existing biofuel technologies and appeals to anyone with an interest in biofuels as renewable energy options and their practical implementation.