Bioenergy Systems for the Future: Prospects for Biofuels and Biohydrogen examines the current advances in biomass conversion technologies for biofuels and biohydrogen production, including their advantages and challenges for real-world application and industrial-scale implementation. In its first part, the book explores the use of lignocellulosic biomass and agricultural wastes as feedstock, also addressing biomass conversion into biofuels, such as bioethanol, biodiesel, bio-methane, and bio-gasoline. The chapters in Part II cover several different pathways for hydrogen production, from biomass, including bioethanol and bio-methane reforming and syngas conversion. They also include a comparison between the most recent conversion technologies and conventional approaches for hydrogen production. Part III presents the status of advanced bioenergy technologies, such as applications of nanotechnology and the use of bio-alcohol in low-temperature fuel cells. The role of advanced bioenergy in a future bioeconomy and the integration of these technologies into existing systems are also discussed, providing a comprehensive, application-oriented overview that is ideal for engineering professionals, researchers, and graduate students involved in bioenergy.

Second and Third Generation of Feedstocks: The Evolution of Biofuels presents a critical analysis of both the applications and potential of bioenergy production from second and third generation feedstocks. The book illustrates different aspects of the processes used for the production of biofuels, dealing specifically with second and third generation feedstocks from biomass and algae. The pretreatment of feedstocks and optimization of various forms of bioenergy are considered, along with the economic aspects of the various processes. In the last few years, industrial research efforts have focused on low cost, large-scale processing for lignocellulosic feedstocks originating from agricultural residues and municipal wastes for bioenergy production. This book shares an insight into the recent developments taking place in this industry, exploring transformation processes as well as biomass and algae conversions.

Ethanol: Science and Engineering reviews the most significant research findings in both ethanol production and utilization. The book's contents are divided into four parts, beginning with an explanation of the chemical reactions involved during the conversion of ethanol to more complex molecules. Other sections focus on various processes and their potential use, the modelling of various chemical processes, and finally, their economic and environmental impact. The book includes the most advanced production processes, new technologies, applications, and the economic role ethanol plays today. The book will be great for researchers and engineers in both academic and industry. The idea of using ethanol as a fuel is one of the most promising options in the arena of alternative fuels because of it versatile use as an intermediate for producing hydrogen via reforming reactions, direct fuel cells feed and/or its production from biomass, which is also considered a sustainable feedstock.

Methanol: Science and Engineering provides a comprehensive review of the chemistry, properties, and current and potential uses and applications of methanol. Divided into four parts, the book begins with a detailed account of current production methods and their economics. The second part deals with the applications of methanol, providing useful insights into future applications. Modeling of the various reactor systems is covered in the next section, with final discussions in the book focusing on the economic and environmental impact of this chemical. Users will find this to be a must-have resource for all researchers and engineers studying alternative energy sources.

Hydrogen is one of the most promising next-generation fuels. It has the highest energy content per unit weight of any known fuel and in comparison to the other known natural gases it is environmentally safe - in fact, its combustion results only in water vapour and energy. This book provides an overview of worldwide research in the use of hydrogen in energy development, its most innovative methods of production and the various steps necessary for the optimization of this product. Topics covered include structured catalysts for process intensification in hydrogen production by reforming processes; bimetallic supported catalysts for hydrocarbons and alcohols reforming reactions; catalysts for hydrogen production from renewable raw materials, by-products and waste; Ni and Cu-based catalysts for methanol and ethanol reforming; transition metal catalysts for hydrogen production by low temperature steam reforming of methane; supercritical water gasification of biomass to produce hydrogen; biofuel starting materials for hydrogen production; modelling of fixed bed membrane reactors for ultrapure hydrogen production; hydrogen production using micro membrane reactors; perovskite membrane reactors; polymeric membrane materials for hydrogen separation; industrial membranes for hydrogen separation; multifunctional hybrid sorption-enhanced membrane reactors; carbon based membranes; and separation of hydrogen isotopes by cryogenic distillation. Hydrogen Production, Separation and Purification for Energy is essential reading for researchers in academia and industry working in energy engineering.