This comprehensive book approaches sustainability from two directions, the reduction of pollution and the maintaining of existing resources, both of which are addressed in a thorough examination of the main chemical processes and their impact. Divided into five sections, each introduced by a leading expert in the field, the book takes the reader through the various types of chemical processes, demonstrating how we must find ways to lower the environmental cost (of both pollution and contributions to climate change) of producing chemicals. Each section consists of several chapters, presenting the latest facts and opinion on the methodologies being adopted by the chemical industry to provide a more sustainable future. A follow-up to Materials for a Sustainable Future (Royal Society of Chemistry 2012), this book will appeal to the same broad readership - industrialists and investors; policy makers in local and central governments; students, teachers, scientists and engineers working in the field; and finally editors, journalists and the general public who need information on the increasingly popular concepts of sustainable living.
Les mer
This comprehensive book approaches sustainability from two directions, the reduction of pollution and the maintaining of existing resources, both of which are addressed in a thorough examination of the main chemical processes and their impact.
Les mer
Introduction; General Concepts in Sustainable Chemical Technologies; Separations and Purifications; Overview by Darrell Patterson; Membrane Separation; Gas Separations using Ionic Liquids; Absorption and Adsorption Processes; Liquid-Liquid Extractions and Stripping (including supercritical fluids); Ionic Liquids and their application to a more sustainable chemistry; Crystallisation in Continuous Flow Processes; Chemical Transformation and Reactors; Overview by Janet Scott; Homogeneous and Heterogeneous Catalysis and Catalytic Reactors; The application of supercritical carbon dioxide extractions of functional compounds for more sustainable future; Processes employing cavitation e.g. ultrasound, hydrodynamic cavitation; Microwave Chemistry and Microwave Reactors; Continuous Flow Processes; Bioelectrochemical Systems for a Sustainable Future; Nanoparticles and their application in sustainable chemistry; Sustainable Processes in the Metal and Mining Industry; Photochemical production of Fine Chemicals; Biochemical Transformations and Reactors; Overview, by Professor David Leak; Enzyme Biotransformations and Reactors; Algae and Bacterial Technologies for Biofuels; Fermentations and  Sustainable Technologies; Process Integration; Overview by Rafiqul Gani; Process Control for Sustainable Processes; Quantifying the Impact of New Materials and Processes Towards Environmentally Sustainable Technology; Systematic Computer Aided Framework for Process Synthesis, Design and Intensification
Les mer
This comprehensive book approaches sustainability from two directions, the reduction of pollution and the maintaining of existing resources, both of which are addressed in a thorough examination of the main chemical processes and their impact. Divided into five sections, each introduced by a leading expert in the field, the book takes the reader through the various types of chemical processes, demonstrating how we must find ways to lower the environmental cost (of both pollution and contributions to climate change) of producing chemicals. Each section consists of a number of chapters, presenting the latest facts and opinion on the methodologies being adopted by the chemical industry to provide a more sustainable future.The chapters have been written by scientists and/or engineers who are experts in their field; this combination allows two different perspectives and expertise to be voiced, thus providing a unique appraisal of sustainable chemical processes. A follow-up to Materials for a Sustainable Future (Royal Society of Chemistry 2012), this book will appeal to the same broad readership - industrialists and investors; policy makers in local and central governments; students, teachers, scientists and engineers working in the field; and finally editors, journalists and the general public who need information on the increasingly popular concepts of sustainable living.
Les mer

Produktdetaljer

ISBN
9781849739757
Publisert
2014-12-16
Utgiver
Vendor
Royal Society of Chemistry
Vekt
1384 gr
Høyde
234 mm
Bredde
156 mm
Aldersnivå
P, 06
Språk
Product language
Engelsk
Format
Product format
Innbundet

Biographical note

Trevor M. Letcher is Emeritus Professor of Chemistry at the University of KwaZulu-Natal, Durban, and a Fellow of the Royal Society of Chemistry. He is a past director of the International Asso- ciation of Chemical Thermodynamics and his research involves the thermodynamics of liquid mixtures and energy from landfill. He has published over 270 publications in peer review journals and edited, written or co-edited 13 books related to his research fields. His latest books are: Materials for a Sustainable Future (RSC, 2012), Unraveling Environmental Disasters (Elsevier, 2012), Future Energy: Improved, Sustainable and Clean Options for our Planet, 2nd edition (Elsevier, 2013) and Volumes Properties: Liquids, Solutions and Vapours (RSC, 2014). Janet L. Scott is a Training Director at the Centre for Sustainable Chemical Technologies (CSCT), University of Bath. She has previously worked in both industry and academia in three different countries: South Africa (University of Cape Town, 1992–1995; R&D Manager, Fine Chemicals Corporation, 1996–1998); Australia (Monash University1999–2006) where she was the deputy director of the Centre for Green Chemistry; and the UK, where she held a Marie Curie Senior Transfer of Knowledge Fellowship at Unilever R&D, Port Sunlight, UK (2006–2008). She maintains an active consulting company working with industry on sustainable chemical solutions and research interests currently centre on bio-derived chemicals and materials. She works closely with chemical engineers and industrial partners at CSCT. Darrell A. Patterson is currently a senior lecturer in chemical engineering and a member of the Centre for Sustainable Chemical Technologies (CSCT) at the University of Bath. He leads the Bath Process Intensification Laboratory and the cross-faculty Bath Mem- brane research cluster Membranes@Bath, the UK’s largest academic cluster of academics focusing on membrane science and technology research. He has previously worked at WS Atkins Consultants (2001–2003), Imperial College London (2003–2005) and the University of Auckland (2005–2011). His research is in three main (but related) areas, all aiming to characterise and produce process intensification to develop more sustainable technologies: membrane science and engineering; catalytic reactions and reactor engineering; and waste- water treatment technologies. He has over 70 papers in these areas (including over 40 peer reviewed journal papers).