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Scarcity of resources and increasing population and energy demands are important issues of the twenty-first century. A multidisciplinary approach is needed to produce suitable alternatives—such as renewable resources—for a more sustainable future. One of the most promising and widely available renewable feedstocks is biomass, which has significant potential for conversion to materials, fuels, and chemicals. In addition, nanomaterials can be designed for a range of applications including energy storage, fuel production, and nanocatalysis. Designing nanomaterials for the valorization of biomass and waste feedstocks is a major step in advancing the application of nanomaterials and helping to move us toward the goal of a sustainable economy. Producing Fuels and Fine Chemicals from Biomass Using Nanomaterials offers a wide-ranging approach to the development of innovative nanomaterials for biomass conversion and the production of energy and high-added-value chemicals, including biochemicals, biomaterials, and biofuels. The book is organized into three parts according to nanomaterial applications: Nanomaterials for Energy Storage and Conversion, Biofuels from Biomass Valorization Using Nanomaterials, and Production of High-Added-Value Chemicals from Biomass Using Nanomaterials. Providing a multidisciplinary perspective, this book covers the most important aspects of topics such as solar energy storage, design of carbonaceous nanomaterials as heterogeneous catalysts for producing biofuels, catalytic reforming of biogas into syngas using a range of nanoparticles, and biofuels production from waste oils and fats. It also describes the design and development of biocatalytic, solid acid, photocatalytic, and nanostructured materials for the conversion of various biomass feedstocks to valuable chemicals as intermediates to end products, such as biopolymers, bioplastics, biofuels, agrochemicals, and pharmaceutical products.
As renewable energy sources, biofuels have tremendous potential to replace fossil fuels in future energy scenarios, offering green alternative energy sources. However, though such fuels could mean a significant reduction in environmental pollution, they are still far from practical implementation due to their high production costs and technical issues. Consequently, efforts are being made around the globe to achieve the cost-effective production of biofuels. In this context, the use of nanomaterials to improve biofuels production efficiency is a vital, emerging area. Nanomaterials are attracting attention due to their versatile physicochemical properties and may improve the production process for various biofuels by acting as catalysts. However, this area is still in its infancy. To improve the practical viability of the biofuels production process, it is essential to focus on the specific type of nanomaterial used, its synthesis, and its specific effects on the process parameters. This book explores the potential advantages and feasibility of various aspects of nanomaterials with regard to improving the current biofuels production process, making it a valuable resource for a broad readership.
Nanomaterials in Biomass Conversion: Advances and Applications for Bioenergy, Biofuels and Bio-based Products critically reviews the basic principles through to the latest advances in the emerging field of nanotechnology for the production of biofuels and bioenergy. Divided into 3 parts, the first five chapters explain the fundamentals of nanomaterials, their properties, characterization, and basic processes for synthesis. Part 2, which constitutes the majority of the book, reviews the various methods and technologies for the conversion of biomass to bioenergy, biofuels, and value-added products using nanomaterials. This includes homogeneous and heterogeneous nano-catalytic systems, nano-photocatalytic conversion, nanomaterial-assisted anaerobic digestion, nanoparticles-immobilized enzymes conversion, the production of biogas, volatile fatty acids, and value-added products, and in carbon capture and conversion to sustainable energy products, as well as the potential of nano-biochar, nano-cellulose, and other nanomaterials in microbial fuel cells, bioelectrochemical systems, and batteries. Finally, Part 3 addresses the techno-economics and financial viability in the context of the circular economy, risk related to toxicology, stability, and environmental impacts, and considers the various challenges and future opportunities of biomass conversion through nanomaterials. Nanomaterials in Biomass Conversion is an invaluable resource for researchers and engineers involved in the production of bioenergy, biofuel, and bioproducts, and will also be of benefit to those interested in environmental remediation, pollution management, and cleaner energy production. Critically examines the role of nanomaterials in the management of waste biomass as applied to bioenergy and biofuels Explains various nanotechnological methods for the conversion of waste biomass into value-added products Discusses the basic principles, operational aspects, ongoing developments, and future perspectives related to the applications of nanotechnologies and nanomaterials in biomass conversion Provides solutions to the key challenges of nanotechnologies and nanomaterials in the conversion of biomass, along with future challenges and risks
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.
The consumption of petroleum has surged during the 20th century, at least partially because of the rise of the automobile industry. Today, fossil fuels such as coal, oil, and natural gas provide more than three quarters of the world's energy. Unfortunately, the growing demand for fossil fuel resources comes at a time of diminishing reserves of these nonrenewable resources. The worldwide reserves of oil are sufficient to supply energy and chemicals for only about another 40 years, causing widening concerns about rising oil prices. The use of biomass to produce energy is only one form of renewable energy that can be utilized to reduce the impact of energy production and use on the global environment. Biomass can be converted into three main products such as energy, biofuels and fine chemicals using a number of different processes. Today, it is a great challenge for researchers to find new environmentally benign methodology for biomass conversion, which are industrially profitable as well. This book focuses on the conversion of biomass to biofuels, bioenergy and fine chemicals with the interface of biotechnology, microbiology, chemistry and materials science. An international scientific authorship summarizes the state-of-the-art of the current research and gives an outlook on future developments.
CONVERTING POWER INTO CHEMICALS AND FUELS Understand the pivotal role that the petrochemical industry will play in the energy transition by integrating renewable or low-carbon alternatives Power into Chemicals and Fuels stresses the versatility of hydrogen as an enabler of the renewable energy system, an energy vector that can be transported and stored, and a fuel for the transportation sector, heating of buildings and providing heat and feedstock to industry. It can reduce both carbon and local emissions, increase energy security and strengthen the economy, as well as support the deployment of renewable power generation such as wind, solar, nuclear and hydro. With a focus on power-to-X technologies, this book discusses the production of basic petrochemicals in such a way as to minimize the carbon footprint and develop procedures that save energy or use energy from renewable sources. Various different power-to-X system configurations are introduced with discussions on their performance, environmental impact, and cost. Technologies for sustainable hydrogen production are covered, focusing on water electrolysis using renewable energy as well as consideration of the remaining challenges for large scale production and integration with other technologies. Power into Chemicals and Fuels readers will also find: Discussion of recent advances in power-into-x technologies for the production of ethylene, propylene, formic acid, and more Coverage of every stage in the power-into-x process, from power generation to upgrading the final product Thermodynamic, technoeconomic, and life cycle assessment analyses of each major process Power into Chemicals and Fuels is a valuable resource for scientists and engineers working in the petrochemicals and hydrocarbons industries, as well as for all industry professionals in these and related fields.
Nanotechnology is changing the world in a very big way, but at the atomic and sub-atomic level. Although the roots of nanotechnology can be traced back to more than a century ago, the last three decades have witnessed an explosion of nano-based technologies and products. This reference work examines the history, current status, and future directions of nanotechnology through an exhaustive search of the technical and scientific literature. The more than 4000 bibliographic citations it includes are carefully organized into core subject areas, and a geographic and subject index allows readers to quickly locate documents of interest. Although a sense of the global reach and interest in nanotechnology can be gleaned from the reference sections of countless journal articles, conference papers, and books, this is the only reference work providing an in-depth global perspective that is ready-made for nanotechnology professionals and those interested in learning more about all things nanotechnology. Despite the abundance of online resources, there is still an urgent need for well-researched, well-presented, concise, and thematically organized reference works. Instead of relying on wiki pages, citation aggregators, and related websites, the author searched the databases and databanks of scholarly literature search providers such as EBSCO, ProQuest, PUBMED, STN International, and Thomson Reuters. In addition, he used select serials-related databases to account for pertinent documents from countries in which English is not the primary national language (i.e., China Online Journals, e-periodica, J-STAGE, and SciELO Brazil among others).
This book provides state-of-the-art reviews, current research, prospects and challenges of the production of biofuels and chemicals such as furanic biofuels, biodiesel, carboxylic acids, polyols and others from lignocellulosic biomass, furfurals, syngas and γ-valerolactone with bifunctional catalysts, including catalytic, and combined biological and chemical catalysis processes. The bifunctionality of catalytic materials is a concept of not only using multifunctional solid materials as activators, but also design of materials in such a way that the catalytic materials have synergistic characteristics that promote a cascade of transformations with performance beyond that of mixed mono-functional catalysts. This book is a reference designed for researchers, academicians and industrialists in the area of catalysis, energy, chemical engineering and biomass conversion. Readers will find the wealth of information contained in chapters both useful and essential, for assessing the production and application of various biofuels and chemicals by chemical catalysis and biological techniques.
This book is an attempt to provide an account of biomass recalcitrance and available physical and chemical methods for biomass pretreatment and hydrolysis. Its focuses on understanding the critical role of enzymes in the development of integrated biorefinery. The book also presents an overview of the utilization of waste biomass as a support system for enzyme immobilization for easy recovery and reuse for multiple cycles. strategies where enzymes can be used. The book also attempts to understand how enzymes can play a vital role in waste valorization for energy and biomaterial production. Further, the book will present an overview of how advanced technologies such as omics and in-silico approaches can help in understanding the chemistry affecting recalcitrance and the mechanism of enzyme catalysts in their bioconversion. An understanding of the life cycle assessment of waste biomass biorefinery will be needed before its implementation. The book will serve as additional reading material for undergraduate and graduate students of energy studies, chemical engineering, applied biotechnology, and environmental sciences. This book is of interest to academicians, scientists, environmentalists, and policymakers.
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.