Filling the need for an up-to-date handbook, this ready reference closely investigates the use of CO2 for ureas, enzymes, carbamates, and isocyanates, as well as its use as a solvent, in electrochemistry, biomass utilization and much more. Edited by an internationally renowned and experienced researcher, this is a comprehensive source for every synthetic chemist in academia and industry.
This book provides an analysis of the reaction mechanisms relevant to a number of processes in which CO2 is converted into valuable products. Several different processes are considered that convert CO2 either in specialty chemicals or in bulk products or fuels. For each reaction, the mechanism is discussed and the assessed steps besides the dark sites of the reaction pathway are highlighted. From the insertion of CO2 into E-X bonds to the reduction of CO2 to CO or other C1 molecules or else to C2 or Cn molecules, the reactions are analysed in order to highlight the known and obscure reaction steps. Besides well known reaction mechanisms and energy profiles, several lesser known situations are discussed. Advancing knowledge of the latter would help to develop efficient routes for the conversion of CO2 into valuable products useful either in the chemical or in the energy industry. The content of this book is quite different from other books reporting the use of CO2. On account of its clear presentation, “Reaction Mechanisms in Carbon Dioxide Conversion” targets in particular researchers, teachers and PhD students.
Biorefineries compiles essential science and technologies for converting terrestrial and aquatic biomass into vital molecular compounds and polymeric materials. This book delves into the recent industrial chemistry concept focused on maximizing economic benefits while minimizing environmental impact. Renowned experts contribute chapters on topics such as catalysis, downstream processing, biomass-sourced olefins, lignin biorefinery techniques, and biogas. The authors provide a thorough examination of the biomass conversion value chain, detailing the transformation of platform molecules into final products. A comprehensive overview presents fundamental concepts for beginners, while numerous full-color figures and tables enhance understanding of the involved techniques. Advanced students and experts will appreciate the summaries of state-of-the-art research and current literature. The text explores the vast potential of biomass conversion as a future source of fuels and chemicals, addressing both general scientific background and current innovations in biorefinery. It targets students and researchers in Chemistry, Chemical Engineering, Biotechnology, and Materials Science. The editors include distinguished professionals with extensive experience and contributions to the field, ensuring a rich and informative resource for readers.
This book provides an introduction to the basic science and technologies for the conversion of biomass (terrestrial and aquatic) into chemicals and fuels, as well as an overview of innovations in the field. The entire value chain for converting raw materials into platform molecules and their transformation into final products are presented in detail. Both cellulosic and oleaginous biomass are considered. The book contains contributions by both academic scientists and industrial technologists so that each topic combines state-of-the-art scientific knowledge with innovative technologies relevant to chemical industries. Selected topics include: Refinery of the future: feedstock, processes, products The terrestrial and aquatic biomass production and properties Chemical technologies and biotechnologies for the conversion of cellulose, hemicellulose, lignine, algae, residual biomass Thermal, catalytic and enzymatic conversion of biomass Production of chemicals, polymeric materials, fuels (biogas, biodiesel, bioethanol, biohydrogen) Policy aspects of biomass product chains LCA applied to the energetic, economic and environmental evaluation of the production of fuels from biomass: ethanol, biooil and biodiesel, biogas, biohydrogen