Book contents
- Frontmatter
- Contents
- Preface
- Acknowledgments
- Acknowledgments for permissions to use illustrations
- 1 Fuels and the global carbon cycle
- 2 Catalysis, enzymes, and proteins
- 3 Photosynthesis and the formation of polysaccharides
- 4 Ethanol
- 5 Plant oils and biodiesel
- 6 Composition and reactions of wood
- 7 Reactive intermediates
- 8 Formation of fossil fuels
- 9 Structure–property relationships among hydrocarbons
- 10 Composition, properties, and processing of natural gas
- 11 Composition, classification, and properties of petroleum
- 12 Petroleum distillation
- 13 Heterogeneous catalysis
- 14 Catalytic routes to gasoline
- 15 Middle distillate fuels
- 16 Thermal processing in refining
- 17 Composition, properties, and classification of coals
- 18 The inorganic chemistry of coals
- 19 Production of synthesis gas
- 20 Gas treatment and shifting
- 21 Uses of synthesis gas
- 22 Direct production of liquid fuels from coal
- 23 Carbonization and coking of coal
- 24 Carbon products from fossil and biofuels
- 25 Carbon dioxide
- Index
- References
2 - Catalysis, enzymes, and proteins
Published online by Cambridge University Press: 05 February 2013
- Frontmatter
- Contents
- Preface
- Acknowledgments
- Acknowledgments for permissions to use illustrations
- 1 Fuels and the global carbon cycle
- 2 Catalysis, enzymes, and proteins
- 3 Photosynthesis and the formation of polysaccharides
- 4 Ethanol
- 5 Plant oils and biodiesel
- 6 Composition and reactions of wood
- 7 Reactive intermediates
- 8 Formation of fossil fuels
- 9 Structure–property relationships among hydrocarbons
- 10 Composition, properties, and processing of natural gas
- 11 Composition, classification, and properties of petroleum
- 12 Petroleum distillation
- 13 Heterogeneous catalysis
- 14 Catalytic routes to gasoline
- 15 Middle distillate fuels
- 16 Thermal processing in refining
- 17 Composition, properties, and classification of coals
- 18 The inorganic chemistry of coals
- 19 Production of synthesis gas
- 20 Gas treatment and shifting
- 21 Uses of synthesis gas
- 22 Direct production of liquid fuels from coal
- 23 Carbonization and coking of coal
- 24 Carbon products from fossil and biofuels
- 25 Carbon dioxide
- Index
- References
Summary
Catalysis
The topic of catalysis recurs throughout fuel chemistry. A catalyst increases the rate of a chemical reaction without itself being permanently altered by the reaction, or appearing among the products. The key word is rate. Catalysts affect reaction kinetics. A catalyst affects reaction rate by providing a different mechanism for the reaction, usually one that has a markedly lower activation energy than that of the non-catalyzed reaction. Catalysts do not change reaction thermodynamics; they do not alter the position of equilibrium [A], but they can help reach equilibrium much more quickly. And, they cannot cause a thermodynamically unfavorable reaction to occur.
Catalysts can be classified as homogeneous, in the same phase as the reactants and products, and heterogeneous, in a separate phase. Homogeneous catalysts mix intimately with the reactants. This good mixing often leads to enormous rate enhancements, in some cases by more than eight orders of magnitude. But, because they are in the same phase as the reactants and products, industrial use would require a separation operation for catalyst recovery downstream of the reaction, unless one were willing to throw away the catalyst (possibly allowing it to contaminate the products) as it passes through the reactor. For many catalytic processes, the catalyst costs much more than the reactants do, so loss of the catalyst would result in a significant economic penalty. Usually, heterogeneous catalysts have no major separation problems, thanks to their being in a separate phase from reactants and products. However, because of their being in a separate phase, mass-transfer limitations can hold up access of the reactants to the catalyst, or hold up departure of products. Heterogeneous catalysis can also be affected by various problems at the catalyst surface (discussed in Chapter 13). Large-scale industrial processing almost always favors use of heterogeneous catalysts, to avoid possibly difficult downstream separation issues. Nevertheless, steady progress is being made in finding ways to overcome separation problems with homogeneous catalysts, including, as examples, membrane separation, selective crystallization, and use of supercritical solvents.
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- Information
- Chemistry of Fossil Fuels and Biofuels , pp. 10 - 18Publisher: Cambridge University PressPrint publication year: 2013