Principles, Processes, and Applications
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Köp båda 2 för 2610 krA complete, up-to-date, introductory guide to fuel cell technology and application Fuel Cell Fundamentals provides a thorough introduction to the principles and practicalities behind fuel cell technology. Beginning with the underlying concepts, th...
RYAN O'HAYRE, Ph.D., is Professor of Metallurgical and Materials Engineering at the Colorado School of Mines, where he directs the Advanced Energy Materials Laboratory, a developer of new materials and devices to enable alternative energy technologies including fuel cells and solar cells. He received his Ph.D. in materials science and engineering from Stanford University.
Preface xiii Acknowledgments xv Learning Objectives xvii I Kinetic Principles 1 Introduction to Materials Kinetics 3 1.1 What Is Kinetics? 3 1.2 Kinetics Versus Thermodynamics 4 1.3 Homogeneous Versus Heterogeneous Kinetics 6 1.4 Reaction Versus Diffusion 7 1.5 Classifying Kinetic Processes 9 1.6 Brief Word about Units 10 1.7 Chapter Summary 11 1.8 Chapter Exercises 12 2 A Short Detour into Thermodynamics 14 2.1 Dynamic Equilibrium 14 2.2 Enthalpy (H), Entropy (S), and Gibbs Free Energy (G) 15 2.2.1 Relationship between G, H, and S 16 2.3 Molar Quantities 18 2.4 Standard State 19 2.5 Calculating Thermodynamic Quantities 20 2.6 Reaction Quotient Q and Equilibrium Constant K 22 2.7 Temperature Dependence of K 28 2.8 Thermodynamics of Phase Transformations 31 2.9 Ideal Gas Law 34 2.10 Calculating Concentrations for Liquids or Solids 36 2.10.1 Calculating Densities/Concentrations in Pure Materials 36 2.10.2 Calculating Densities/Concentrations in Stoichiometric Compounds or Dilute Solutions 37 2.10.3 Calculating Densities/Concentrations for Mixtures of Multiple Phases/Compounds 39 2.10.4 Calculating Densities/Concentrations from Crystallographic Information 41 2.10.5 Calculating Site Fractions 42 2.11 Chapter Summary 44 2.12 Chapter Exercises 46 3 Chemical Reaction Kinetics 48 3.1 Homogeneous versus Heterogeneous Chemical Reactions 50 3.2 Homogeneous Chemical Reactions 51 3.2.1 Reaction Rate Equation and k 51 3.2.2 Order of Reaction 51 3.2.3 Zero-Order Reactions 53 3.2.4 First-Order Reactions 54 3.2.5 Second-Order Reactions 58 3.2.6 Incomplete Reactions/Equilibrium Reactions 64 3.2.7 Summary of Homogeneous Reaction Kinetics 68 3.3 Temperature Dependence of Reaction Kinetics: Activation Theory 68 3.4 Heterogeneous Chemical Reactions 72 3.4.1 Effect of Catalyst 72 3.4.2 GasSolid Surface Reaction Processes 75 3.5 Chapter Summary 79 3.6 Chapter Exercises 81 4 Transport Kinetics (Diffusion) 84 4.1 Flux 85 4.2 Fluxes and Forces 87 4.3 Common Transport Modes (Force/Flux Pairs) 88 4.4 Phenomenological Treatment of Diffusion 90 4.4.1 Steady-State Diffusion: Ficks First Law 91 4.4.2 Transient Diffusion: Ficks Second Law 94 4.4.3 Kirkendal Effect and Moving Interface Problems 118 4.4.4 Summary of Transient Diffusion Problems 120 4.4.5 Coupled Diffusion Processes 120 4.5 Atomistic Treatment of Diffusion 125 4.5.1 Overview of Diffusion in Gases Versus Liquids Versus Solids 125 4.5.2 Diffusion in Gases: Kinetic Theory of Gases 126 4.5.3 Diffusion in Solids: Atomistic Mechanisms of Solid-State Diffusion 130 4.5.4 Diffusion in Solids: High-Diffusivity Paths 135 4.6 Chapter Summary 139 4.7 Chapter Exercises 142 II Applications of Materials Kinetics 5 GasSolid Kinetic Processes 151 5.1 Adsorption/Desorption 151 5.2 Active Gas Corrosion 157 5.3 Chemical Vapor Deposition 166 5.4 Atomic Layer Deposition 176 5.5 Passive Oxidation 179 5.6 Chapter Summary 184 5.7 Chapter Exercises 187 6 LiquidSolid and SolidSolid Phase Transformations 190 6.1 What Is a Phase Transformation? 190 6.2 Driving Forces for Transformation: Temperature and Composition 192 6.2.1 Calculating GV 193 6.3 Spinodal Decomposition: A Continuous Phase Transformation 197 6.4 Surfaces and Interfaces 199 6.4.1 Estimating Surface Energies 200 6.4.2 Interfacial Energy Balances 203 6.4.3 Overview of Important Surface/Interface Energy Effects 205 6.5 Nucleation 205 6.5.1 Homogeneous Nucleation 206 6.5.2 Heterogeneous Nucleation 212 6.5.3 Nucleation Rate 218 6.6 Growth 221 6.7 Nucleation and Growth Combined 226 6.7.1 Effect of Nucleation Rate versus Growth Rate on Microstructure 226 6.7.2 Overall Rate of Transformation: JohnsonMehl and Avrami Equations 229 6.7.3 TimeTemperatureTransformation Diagrams 230 6.8 Solidification 232 6.8.1 Casting Microstructures 233 6.8.2 Plane Fron