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PREFACE<br> <br> PART ONE: Introduction<br> <br> WHAT IS FISCHER -<br> TROPSCH? <br> Feedstocks for Fuel and for Chemicals Manufacture <br> The Problems <br> Fuels for Transportation <br> Feedstocks for the Chemical Industry <br> Sustainability and Renewables: Alternatives to Fossil Fuels <br> The Way Forward <br> XTL and the Fischer -<br> Tropsch Process (FTP) <br> Alternatives to Fischer -<br> Tropsch<br> <br> PART TWO: Industrial and Economics Aspects <br> <br> SYNGAS: THE BASIS OF FISCHER -<br> TROPSCH<br> Syngas as Feedstock 19<br> Routes to Syngas: XTL (X ? Gas, Coal, Biomass, and Waste) <br> Water-Gas Shift Reaction (WGSR) <br> Synthesis Gas Cleanup<br> Thermal and Carbon Efficiency <br> The XTL Gas Loop<br> CO2 Production and CO2 as Feedstock 46<br> <br> FISCHER -<br> TROPSCH TECHNOLOGY<br> Introduction<br> Industrially Applied FT Technologies <br> FT Catalysts <br> Requirements for Industrial Catalysts <br> FT Reactors<br> Selecting the Right FT Technology <br> Selecting the FT Operating Conditions<br> Selecting the FT Catalyst Type<br> Other Factors That Affect FT Technology Selection <br> <br> WHAT CAN WE DO WITH FISCHER -<br> TROPSCH PRODUCTS? <br> Introduction<br> Composition of Fischer -<br> Tropsch Syncrude<br> Syncrude Recovery after Fischer -<br> Tropsch Synthesis<br> Fuel Products from Fischer -<br> Tropsch Syncrude <br> Lubricants from Fischer -<br> Tropsch Syncrude <br> Petrochemical Products from Fischer -<br> Tropsch Syncrude <br> <br> INDUSTRIAL CASE STUDIES <br> Introduction <br> A Brief History of Industrial FT Development <br> Industrial FT Facilities <br> Perspectives on Industrial Developments<br> <br> OTHER INDUSTRIALLY IMPORTANT SYNGAS REACTIONS <br> Survey of CO Hydrogenation Reactions <br> Syngas to Methanol <br> Syngas to Dimethyl Ether (DME) <br> Syngas to Ethanol <br> Syngas to Acetic Acid <br> Higher Hydrocarbons and Higher Oxygenates<br> Hydroformylation<br> Other Reactions Based on Syngas<br> <br> FISCHER -<br> TROPSCH PROCESS ECONOMICS <br> Introduction and Background <br> Market Outlook (Natural Gas) <br> Capital Cost <br> Operating Costs <br> Revenues <br> Economics and Sensitivity Analysis<br> <br> PART THREE: Fundamental Aspects<br> <br> PREPARATION OF IRON FT CATALYSTS <br> Introduction <br> High-Temperature Fischer -<br> Tropsch (HTFT) Catalysts <br> Low-Temperature Catalysts <br> Individual Steps <br> <br> COBALT FT CATALYSTS<br> Introduction <br> Early German Work<br> Support Preparation <br> Addition of Cobalt and Promoters<br> Calcination<br> Reduction<br> Catalyst Transfer<br> Catalyst Attrition <br> Addendum Recent Literature Summary <br> <br> OTHER FT CATALYSTS<br> Introduction<br> Ni Catalysts <br> Ruthenium Catalysts <br> Rhodium Catalysts<br> Other Catalysts and Promoters <br> <br> SURFACE SCIENCE STUDIES RELATED TO FISCHER?TROPSCH REACTIONS<br> Introduction: Surfaces in Catalysts and Catalytic Cycles<br> Heterogeneous Catalyst Characterization <br> Species Detected on Surfaces <br> Theoretical Calculations <br> <br> MECHANISTIC STUDIES RELATED TO THE FISCHER -<br> TROPSCH HYDROCARBON SYNTHESIS AND SOME COGNATE PROCESSES <br> Introduction <br> Basic FT Reaction: Dissociative and Associative Paths <br> Some Mechanisms-Related Experimental Studies<br> Current Views on the Mechanisms of the FT-S<br> Now: Toward a Consensus? <br> Dual FT Mechanisms <br> Cognate Processes: The Formation of Oxygenates in FT-S<br> Dual Mechanisms Summary <br> Improvements by Catalyst Modifications <br> Catalyst Activation and Deactivation Processes <br> Desorption and Displacement Effects <br> Directions for Future Researches <br> Caveat <br> <br> PART FOUR: Environmental Aspects <br> <br> FISCHER -<br> TROPSCH CATALYST LIFE CYCLE <br> Introduction<br> Catalyst Manufacturing<br> Catalyst Consumption <br> Catalyst Disposal <br> <br> FISCHER -<br> TROPSCH SYNCRUDE: TO REFINE OR TO UPGRADE? <br> Introduction<br> Wax Hydrocracking and Hydroisomerization <br> Olefin Dimerization and Oligomerization <br> <br> ENVIRONMENTAL SUSTAINABILITY<br> Introduction<br> Impact of FT Facilities on the Environment <br> Water and Wastewater Management <br> Solid Waste Management <br> Air Quality Management <br> Environmental Footprint of FT Refineries <br> <br> PART FIVE: Future Prospects<br> <br> NEW DIRECTIONS, CHALLENGES, AND OPPORTUNITIES <br> Introduction <br> Why Go Along the Fischer -<br> Tropsch Route?<br> Considerations against Fischer -<br> Tropsch Facilities <br> Opportunities to Improve Fischer -<br> Tropsch Facilities <br> Fundamental Studies: Keys to Improved FT Processes <br> Challenges for the Future<br> Conclusions <br> <br> GLOSSARY <br> <br> INDEX <br>

<p><b><i>Peter Maitlis</i></b> is Professor Emeritus of Inorganic Chemistry at the University of Sheffield. His researches are concerned with the interaction of organic molecules with metals, where he is currently developing a closer understanding of heterogeneously catalyzed reactions. He has co-authored over 350 scientific papers as well as three books on catalysis, and has lectured extensively. His work has been recognized internationally: he was elected FRS in 1984, and was made a Socio of the Accademia dei Lincei in Rome in 1999. He has been President of the Dalton Division of the RSC, Chairman, of the SERC Chemistry Committee in the UK, and has also worked in the USA (Cornell and Harvard), and in Canada (McMaster University).</p> <p><b><i>Arno de Klerk</i></b> holds postgraduate qualifications in both analytical chemistry and chemical engineering. In 2001 he was appointed as research manager of the Fischer-Tropsch Refinery Catalysis group, being responsible for catalysis research related to conversion processes for upgrading Fischer-Tropsch syncrude to fuels and chemicals. In 2009 he relocated from South Africa to Canada and took up his present position at the University of Alberta. He has authored publications in the fields of engineering, catalysis, chemistry and refining. He is author of the book “Fischer-Tropsch Refining” also published by Wiley-VCH (ISBN 978-3-527-32605-1).</p>

<p>How can we use our carbon-based resources in the most responsible manner? How can we most efficiently transform natural gas, coal, or biomass into diesel, jet fuel or gasoline to drive our machines? The Big Questions today are energy-related, and the Fischer-Tropsch process provides industrially tested solutions.</p> <p>This book offers a comprehensive and up-to-date overview of the Fischer-Tropsch process, from the basic science and engineering to commercial issues. It covers industrial, economic, environmental, and fundamental aspects, with a specific focus on “green” concepts such as sustainability, process improvement, waste-reduction, and environmental care. <p>The result is a practical reference for researchers, engineers, and financial analysts working in the energy sector, who are interested in carbon conversion, fuel processing or synthetic fuel technologies. It is also an ideal introductory book on the Fischer-Tropsch process for graduate courses in chemistry and chemical engineering.

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