Catalytic Kinetics

Chemistry and Engineering

2nd Edition - June 4, 2016
Authors: Dmitry Yu Murzin, Tapio Salmi
Language: English
eBook ISBN:
9 7 8 - 0 - 4 4 4 - 6 3 4 6 3 - 4

Catalytic Kinetics: Chemistry and Engineering, Second Edition offers a unified view that homogeneous, heterogeneous, and enzymatic catalysis form the cornerstone of practical… Read more

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Catalytic Kinetics: Chemistry and Engineering, Second Edition offers a unified view that homogeneous, heterogeneous, and enzymatic catalysis form the cornerstone of practical catalysis.

The book has an integrated, cross-disciplinary approach to kinetics and transport phenomena in catalysis, but still recognizes the fundamental differences between different types of catalysis. In addition, the book focuses on a quantitative chemical understanding and links the mathematical approach to kinetics with chemistry.

A diverse group of catalysts is covered, including catalysis by acids, organometallic complexes, solid inorganic materials, and enzymes, and this fully updated second edition contains a new chapter on the concepts of cascade catalysis. Finally, expanded content in this edition provides more in-depth discussion, including topics such as organocatalysis, enzymatic kinetics, nonlinear dynamics, solvent effects, nanokinetics, and kinetic isotope effects.

Chapter 1: Setting the Scene

Abstract
1.1 History
1.2 Catalysis
1.3 Formal Kinetics
1.4 Acquisition of Kinetic Data
1.5 Kinetics and Thermodynamics
1.6 Examples and Exercises

Chapter 2: Catalysis

Abstract
2.1 Homogeneous Catalysis
2.2 Heterogeneous Catalysis
2.3 Organocatalysis
2.4 Examples and Exercises

Chapter 3: Elementary Reactions

Abstract
3.1 Reaction Rate Theory
3.2 Elementary Reactions in Solutions
3.3 Reaction Mechanism
3.4 Quasi-equilibrium Approximation
3.5 Relationship Between Thermodynamics and Kinetics
3.6 Transition State Theory of Surface Reactions
3.7 Rates of Reactions on Nonideal Surfaces
3.8 Deterministic and Stochastic Models
3.9 Microkinetic Modeling
3.10 Compensation Effect
3.11 Isotope Effects
3.12 Examples and Exercises

Chapter 4: Complex Reactions

Abstract
4.1 Steady State Kinetics of Complex Reactions
4.2 Basic Routes of Complex Reactions
4.3 Single-Route Steady-State Reaction
4.4 Topological Analysis of Complex Reactions
4.5 Electrical Analogy of Reaction Networks
4.6 Thermodynamic Consistency of Rate Constants for Complex Networks
4.7 Kinetic Aspects of Selectivity
4.8 Parallel Reactions: Kinetic Coupling
4.9 Reduction of Complexity
4.10 Polynomial Kinetics
4.11 Examples and Exercises

Chapter 5: Homogeneous Catalytic Kinetics

Abstract
5.1 Homogeneous Acid-Base Catalysis
5.2 Nucleophilic Catalysis
5.3 Catalysis by Metal Ions
5.4 Catalysis by Organometallic Complexes
5.5 Organocatalysis
5.6 Polymerization Catalysis
5.7 Examples and Exercises

Chapter 6: Enzymatic Kinetics

Abstract
6.1 Enzymatic Catalysis
6.2 Cooperative Kinetics
6.3 Inhibition
6.4 Effects of pH
6.5 Single Molecule Enzymology
6.6 Enantioselectivity in Enzyme Catalyzed Reactions
6.7 Generalized Rate Laws for Enzymatic Reactions
6.8 Heterogeneous Systems/Immobilized Enzymes
6.9 Examples and Exercises

Chapter 7: Heterogeneous Catalytic Kinetics

Abstract
7.1 Reactions on Ideal Surfaces
7.2 Reactions on Nonideal Surfaces
7.3 Selectivity
7.4 Polyatomic Nature of Reactants and Coverage-Dependent Adsorption Mode
7.5 Solvent Effects
7.6 Ionic Species
7.7 Transfer of Labeled Atoms in Heterogeneous Catalytic Reactions
7.8 Electrocatalytic Kinetics
7.9 Photocatalytic Kinetics
7.10 Nanokinetics
7.11 Examples and Exercises

Chapter 8: Kinetics of Catalytic Reactions With Multiple/Multifunctional Catalysts

Abstract
8.1 General
8.2 Combined Catalytic and Noncatalytic Reactions
8.3 Multiple Catalysts of the Same Type
8.4 Multiple Catalysts of Different Types
8.5 Examples and Exercises

Chapter 9: Dynamic Catalysis

Abstract
9.1 Transient Kinetics
9.2 Relaxation Methods
9.3 Temperature-Programmed Desorption
9.4 Oscillations
9.5 Dynamic Catalyst Changes
9.6 Examples and Exercises

Chapter 10: Mass Transfer and Catalytic Reactions

Abstract
10.1 Catalytic Multi-Phase Systems
10.2 Simultaneous Reaction and Diffusion in Fluid Films and in Porous Materials
10.3 Liquid-Liquid Diffusion, Phase-Transfer Catalysis
10.4 Catalytic Two-Phase Systems
10.5 Mass Transfer and Enzymatic Kinetics
10.6 External Mass Transfer
10.7 Internal Diffusion and Selectivity
10.8 Internal Diffusion and Deactivation
10.9 Elucidation of the Impact of Mass Transfer
10.10 Three-Phase Systems
10.11 Examples and Exercises

Chapter 11: Kinetic Modeling

Abstract
11.1 Basic Principles
11.2 Heuristic Design of Experiments
11.3 Parameter Estimation: Classical Methods
11.4 Parameter Estimation: Regression
11.5 Numerical Strategies
11.6 Analysis of Parameters
11.7 Model Discrimination
11.8 Software
11.9 Case Studies

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Dmitry Yu Murzin

Tapio Salmi

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