- ホーム
- > 洋書
- > ドイツ書
- > Mathematics, Sciences & Technology
- > Chemistry
- > physical chemistry
Full Description
The Nobel Prize in Chemistry 2007 awarded to Gerhard Ertl for his groundbreaking studies in surface chemistry highlighted the importance
of heterogeneous catalysis not only for modern chemical industry but also for environmental protection. Heterogeneous catalysis is seen as
one of the key technologies which could solve the challenges associated with the increasing diversification of raw materials and energy sources. It is the decisive step in most chemical industry processes, a major method of reducing pollutant emissions from mobile sources and is present in fuel cells to produce electricity. The increasing power of computers over the last decades has led to modeling and numerical
simulation becoming valuable tools in heterogeneous catalysis.
This book covers many aspects, from the state-of-the-art in modeling and simulations of heterogeneous catalytic reactions on a molecular level to heterogeneous catalytic reactions from an engineering perspective. This first book on the topic conveys expert knowledge from surface
science to both chemists and engineers interested in heterogeneous catalysis. The well-known and international authors comprehensively
present many aspects of the wide bridge between surface science and catalytic technologies, including DFT calculations, reaction dynamics
on surfaces, Monte Carlo simulations, heterogeneous reaction rates, reactions in porous media, electro-catalytic reactions, technical reactors,
and perspectives of chemical and automobile industry on modeling heterogeneous catalysis. The result is a one-stop reference for theoretical
and physical chemists, catalysis researchers, materials scientists, chemical engineers, and chemists in industry who would like to broaden
their horizon and get a substantial overview on the different aspects of modeling and simulation of heterogeneous catalytic reactions.
Contents
Preface
MODELING CATALYTIC REACTIONS ON SURFACES WITH DENSITY FUNCTIONAL THEORY
Introduction
Theoretical Background
The Electrocatalytic Oxygen Reduction Reaction on Pt(111)
Conclusions
DYNAMICS OF REACTIONS AT SURFACES
Introduction
Theoretical and Computational Foundations of Dynamical Simulations
Interpolation of Potential Energy Surfaces
Quantum Dynamics of Reactions at Surfaces
Nondissociative Molecular Adsorption Dynamics
Adsorption Dynamics on Precovered Surfaces
Relaxation Dynamics of Dissociated H2 Molecules
Electronically Nonadiabatic Reaction Dynamics
Conclusions
FIRST-PRINCIPLES KINETIC MONTE CARLO SIMULATIONS FOR HETEROGENEOUS CATALYSIS: CONCEPTS, STATUS, AND FRONTIERS
Introduction
Concepts and Methodology
A Showcase
Frontiers
Conclusions
MODELING THE RATE OF HETEROGENEOUS REACTIONS
Introduction
Modeling the Rates of Chemical Reactions in the Gas Phase
Computation of Surface Reaction Rates on a Molecular Basis
Models Applicable for Numerical Simulation of Technical Catalytic Reactors
Simplifying Complex Kinetic Schemes
Summary and Outlook
MODELING REACTIONS IN POROUS MEDIA
Introduction
Modeling Porous Structures and Surface Roughness
Diffusion
Diffusion and Reaction
Pore Structure Optimization: Synthesis
Conclusion
MODELING POROUS MEDIA TRANSPORT, HETEROGENEOUS THERMAL CHEMISTRY, AND ELECTROCHEMICAL CHARGE TRANSFER
Introduction
Qualitative Illustration
Gas-Phase Conservation Equations
Ion and Electron Transport
Charge Conservation
Thermal Energy
Chemical Kinetics
Computational Algorithm
Button Cell Example
Summary and Conclusions
EVALUATION OF MODELS FOR HETEROGENEOUS CATALYSIS
Introduction
Surface and Gas-Phase Diagnostic Methods
Evaluation of Hetero/Homogeneous Chemical Reaction Schemes
Evaluation of Transport
Conclusions
COMPUTATIONAL FLUID DYNAMICS OF CATALYTIC REACTORS
Introduction
Modeling of Reactive Flows
Coupling of the Flow Field with Heterogeneous Chemical Reactions
Numerical Methods and Computational Tools
Reactor Simulations
Summary and Outlook
PERSPECTIVE OF INDUSTRY ON MODELING CATALYSIS
The Industrial Challenge
The Dual Approach
The Role of Modeling
Examples of Modeling and Scale-Up of Industrial Processes
Conclusions
PERSPECTIVES OF THE AUTOMOTIVE INDUSTRY ON THE MODELING OF EXHAUST GAS AFTERTREATMENT CATALYSTS
Introduction
Emission Legislation
Exhaust Gas Aftertreatment Technologies
Modeling of Catalytic Monoliths
Modeling of Diesel Particulate Filters
Selective Catalytic Reduction by NH3 (Urea-SCR) Modeling
Diesel Oxidation Catalyst, Three-Way Catalyst, and NOx Storage and Reduction Catalyst Modeling
Modeling Catalytic Effects in Diesel Particulate Filters
Determination of Global Kinetic Parameters
Challenges for Global Kinetic Models
System Modeling of Combined Exhaust Aftertreatment Systems
Conclusion
