Bioenergy Engineering: Fundamentals, Methods, Modelling, and Applications presents the fundamental principles, recent developments, innovative state-of the-art technologies, challenges, solutions and future perspectives on the production of biofuels and bioenergy. Balancing the scientific and engineering aspects of biofuels production, the book guides readers through the chemical kinetics, modeling, thermodynamics, unit operations and technological advancements in fuel processing from conventional and alternative resources. Each chapter of the book starts with the fundamentals and goes on to assess the latest technologies for the production of renewable fuels on topics. Sections cover biomass utilization, biomass-to-liquid conversion technologies (pyrolysis, liquefaction, solid-state fermentation and submerged fermentation), biomass-to-gas conversion technologies (thermochemical gasification, subcritical and supercritical water gasification, and methanation), gas-to-liquid conversion technologies (Fischer-Tropsch synthesis), carbonization, transesterification, organic transformation, carbon-carbon and carbon-heteroatom coupling reactions, oxidation, reforming, hydrotreating technologies (hydrogenation, hydrodesulfurization, hydrodenitrogenation, hydro dearomatization and hydro demetalization), nanocatalysis and biocatalysis (enzymatic hydrolysis), and much more.

Biohydrogen is a promising gaseous biofuel that has prospective applications in combined heat and power, for fuel cells, or as a precursor for chemicals production. Hydrogen can also be converted to liquid hydrocarbon fuels and value-added chemicals through catalytic thermochemical or through biocatalytic biological pathways. This book covers some the important recent advances in the production and utilization of biohydrogen and its solutions for clean fuel, waste management, waste valorization, reduced greenhouse gas emissions, and climate change mitigation. Biohydrogen: Developments and Prospects first covers the basic principles, benefits, and challenges concerning both the biological and thermochemical routes for biohydrogen production and then goes on to address topics such as biomass conversion to hydrogen through gasification with a focus on the process parameters, catalytic reforming technologies for hydrogen production concerning various feedstocks; the co-conversion of plastic wastes and biomass into biohydrogen through co-gasification technology; the effect of process parameters on syngas yields through co-gasification; fermentative hydrogen production technologies; the molecular mechanism of hydrogen production and enhancing the yield in hydrogen production by genetic and metabolic engineering; hydrogen production routes through microbial electrolysis; and much more. Key features: Helps to provide the most up-to-date information addressing solutions for clean fuel, waste management, waste valorization, reduced greenhouse gas emissions, and climate change mitigation Offers in-depth knowledge about recent developments on thermochemical methanation technologies and bioreactor and bioprocess design in anaerobic digestion technologies Discusses biotechnological interventions for metabolic engineering of microorganisms towards biohydrogen production Looks at gasification technologies and catalytic reforming technologies for hydrogen production Addressing both the fundamentals as well as advanced new technological research on biohydrogen production by focusing on recent global research with emphasis on the technological, environmental, socioeconomic, and techno-economic aspects, this volume will be a valuable resource for faculty and advanced students, chemical and biochemical engineers, bioprocess technologists, biochemists, environmental scientists and researchers as well as theoretical and applied statisticians and policymakers in this area.

This book presents a comprehensive synopsis of the production and utilization of biomethane along with important recent advances. Biomethane production offers valuable alternative energy solutions for the replacement of fossil fuels to lessen the environmental impacts and strategize for mitigating global warming and climate change. Chapters first focus on the production of biogas (or biomethane) with emphasis on the different biomass utilization for industrial and domestic applications and describe the characteristics, parameters, and process design of anaerobic digesters for biomethane production from waste biomass. The book then goes on to discuss advanced genetic engineering tools and techniques to enhance biomethanation and biomethane production. The volume also offers a state-of-the-art review of anaerobic digestion of biogenic solid wastes, the impact of different chemical pretreatment processes and products, and the influence of operating parameters on biomethane yields. Differentiating between the thermochemical technologies (e.g., gasification and pyrolysis) and biological technologies (e.g., anaerobic digestion) for biomethane production, the book assesses some recent advancements in biomethane production along with its socioeconomic impacts and applications. Other topics include gasification technology and syngas cleaning for biosynthetic natural gas production, the use of catalysts for enhanced synthetic natural gas production, biohythane fuel produced from microbial fermentative pathways, and more. Biomethane: Developments and Prospects offers valuable insight and information on the current status of production and utilization of biomethane that has cross-disciplinary value in biotechnology, fermentation technology, bioprocess engineering, chemical engineering, and environmental technology with a common interest in biofuels and bioenergy.

The major issues relating to environmental sustainability such as a heavy dependency on fossil fuels, increased greenhouse gas emissions, pollution, global warming and climate change have prompted many efforts around the globe to seek alternative energy sources that have negligible environmental impacts and societal benefits. There is an immense interest in biofuels research throughout the world owing to its massive potential to address environmental concerns. Biofuels have the capacity to supplement current and future energy demands through being blended with fossil fuels or even replacing them completely as drop-in fuels in automobiles as well as for heating and the power industries. Waste biomass, primarily lignocellulosic biomass (e.g. agricultural crop residues, forestry biomass and energy crops) and microalgae can act as some inexpensive renewable bioresources for the production of biofuels and biochemicals. The prime focus of Bioprocessing of Biofuels is to shed light on this significant process, especially through microbial conversion technologies to recover and transform the inedible polysaccharides into hydrocarbon biofuels and bioenergy. The book offers introductory coverage of the most crucial topics as follows: A systematic overview of the state-of-the-art in the production and utilization of biofuels Categorical bioprospecting of bioresources for biofuel production Biomass pretreatment and enzymatic saccharification Bioconversion of waste biomass and algae to liquid and gaseous biofuels New developments in microbial fuel-cell technologies Bioprocessing of Biofuels unites topics related to the cutting-edge applications of bioresources and green technologies to reinvigorate biorefineries, positioning them within a competitive energy market. Written to be instantly applicable, this volume offers a reference book for undergraduate and graduate students, scientific investigators and research scholars around the globe working in the areas relating to energy and fuels.

This book provides different aspects on fuel processing and refinery for energy generation. Most updated research findings along with case studies, real scenario examples, and extensive analyses of original research work and literature reviews is included in this book.