Kinetics in Materials Science and Engineering

*Click here for a Q&A session with the author: https://www.crcpress.com/go/9781138732469_authorQA Dennis W. Readey is University Emeritus Professor of Metallurgical and Materials Engineering at the Colorado School of Mines, where he served as the H. F. Coors Distinguished Professor of Ceramic Engineering and Director of the Colorado Center for Advanced Ceramics for seventeen years. Prior to that, he served as chairman of the Department of Ceramic Engineering at Ohio State University. He has been performing research on kinetic processes in materials for almost fifty years and teaching the subject for over thirty years. Before entering academia, he was a program manager in the Division of Physical Research of what is now the Department of Energy, where he was responsible for funding materials research in universities and national laboratories. Earlier, he was also group leader in the Research Division of the Raytheon Company and in the Materials Division of Argonne National Laboratory. He had been active in the Accreditation Board for Engineering and Technology (ABET) for a number of years representing TMS (The Mining, Minerals, and Materials Society) and served on several government committees including the Space Sciences Board and the National Materials Advisory Board of the National Academy of Sciences. He is a member of several professional societies and is a fellow of ASM International (formerly the American Society of Metals) and a fellow, distinguished life member, and Past-President of the American Ceramic Society. Dr. Readey’s research has involved gaseous and aqueous corrosion of ceramics, the effect of atmospheres on sintering, the properties of porous ceramics, processing and properties of ceramic-metal composites, and the electronic properties of compounds, particularly transparent conducting oxides and microwave and infrared materials. He advised 29 Ph.D. and 42 M.S. degree theses, which generated about 120 publications and 13 patents. He received a B.S. degree in metallurgical engineering from the University of Notre Dame and a Sc.D. in ceramic engineering from MIT.

Introduction to Kinetics


Kinetics and Materials Science and Engineering


Materials Science and Engineering


Microstructure


History of Materials Science and Engineering as a Discipline


Impact of Materials Science and Engineering


This Book


Reaction Kinetics


Introduction to Kinetic Processes in Materials


Material Transport and Reaction Rates


Dissolution of NaCl and Al2O3 Contrasting Diffusion and Reaction Control


Homogeneous and Heterogeneous Reactions


Homogeneous Reaction Rates


Reaction Order


Zero Order Reaction


First Order Reaction


Example of First Order Reaction: COCl2 Decomposition


Radioactive Decay and Related Nuclear Reactions


Radiocarbon Dating


Importance of First Order Reactions in Materials


More Complex Reactions


Pseudo First Order Reactions


Second Order Reactions


Reactions that Reach Equilibrium


Parallel Reactions


Series Reactions


Higher Order Reactions


Complexity of Real Reactions: HI and H2O formation


Appendix: Two Reactions in Series


Temperature Dependence of the Reaction Rate Constant


Arrhenius Equation: k = k0 exp(-Q/RT)


Hindenburg Disaster


Adiabatic Flame Temperature


Combustion Synthesis


Barometric Formula


Boltzmann Distribution


Activated State


Catalysts: Pt, Ziegler-Natta


Heterogeneous Reactions: Gas-Solid


Passive Corrosion: SiO2


Active Corrosion: Si, Cr, SiC


Materials Processes: Kroll Process, Siemens Process, Optical Fibers, and Halogen Lamps


Chemical Vapor Deposition of Si: Deposition Processes and Epitaxy


Deposition of Silicon from Trichlorosilane


Active Gas Corrosion of Silicon


Carbon-Carbon Composites: Chemical Vapor Infiltration and Shuttle Columbia Accident


Halogen Lamps


Common Phenomena: Kinetic and Thermodynamic Factors and Growth Rate


Phase Transformations


Thermodynamics of Surfaces and Its Effects


Surface Energy: Origin and Importance


Surface Reconstruction


Typical Values


Surface Energy and Curvature


Curvature and Vapor Pressure


Curvature and Solubility


Curvature and Phase Stability


Ostwald Ripening by Reaction


Freezing Point Depression


Specific Surface Area


Wetting


Interfacial Energies and Microstructure


Interfacial Energies and Morphology


Interfacial "Phases"


Capillary Rise


Surface Segregation


Phase Transitions


Thermodynamics


Rates of Phase Transitions


Transitions in One-Component Solids


Transitions in Multi-Component Systems


Qualitative: Nucleation and Growth and Spinodal Decomposition


Quantitative: Nucleation and Growth


Nucleation Rate


Overall Rate of Phase Transformations: Johnson-Mehl-Avrami Equation


Precipitation


Crystallization of Polyethylene


Heterogeneous Nucleation


Appendix A: Kinetic Energy and Speed of Gas Molecules


Appendix B: Boltzmann Distribution


Appendix C: Maxwell-Boltzmann Speed Distribution


Appendix D: Mean Molecular Speed in a Gas


Appendix E: Exact Result for Molecular Surface Collision Rate


Appendix F: Langmuir Adsorption Isotherm


Diffusion in Ideal Systems


Introduction to Diffusion


The Diffusion Process


Fick's First Law


Values of Diffusion Coefficients: D = 1/3 λv, Gases, Solids, and Liquids


Fick's Second Law: Conservation of Mass


Solving Diffusion Problems: Boundary and Initial Conditions


Infinite and Semi-Infinite Boundary Conditions


Finite Boundary Conditions


Steady-State versus Equilibrium


Measurement of Diffusion Coefficients


Appendix A: Fick's Second Law in Cylindrical Coordinates


Appendix B: Fick's Second Law in Spherical Coordinates


Atomistic Mechanisms of Diffusion in Solids and Gases


Introduction: Magnitudes and T-Dependencies, Why Not Liquids?


Energy Absorption by Atoms and Molecules and Gases and Solids


Interstitial Diffusion in Solids


Vacancy Diffusion in Solids


Statistical Mechanics Approach: Vacancy "Concentrations"


Regular Solution Approach


Quasi-Chemical Approach: "Point Defect Chemistry"


Point Defect Charges: Kröger-Vink Notation


Intrinsic Point Defects in Compounds: Schottky Defects


Implications of Vacancy Diffusion


Intrinsic Vacancy Diffusion


Surface and Grain Boundary Diffusion


Reptation in Polymers


Diffusion in Gases


Mean Free Path in a Gas


Gas Diffusion Coefficient


Chapman-Enskog Equation


Kundsen Diffusion


Appendix A: Vibrational Frequency


Appendix B: Vacancy Concentrations for Schottky Defects, NaCl, and Al2O3


Steady-State Diffusion


Gas Diffusion through Solids


Polymer Gas Separation Membranes


Gas Diffusion through Metals


Cylindrical and Spherical Coordinates


Hydrogen Diffusion in a Glass Laser Fusion Sphere


Passive Oxidation of Silicon


Review of Glass Structure and Properties: Glass Transition and Shuttle Challenger Accident


CO2 Diffusion through a Biological Cell Wall


CVD of Si from SiHCl3 by Diffusion


CVD of Si with Both Reaction and Diffusion


Evaporation of a Water Drop


Dissolution of NaCl


Dissolution of Spheroidized Cementite in Austenite


Common Phenomena: Kinetic and Thermodynamic Factors and Growth Rate


Ostwald Ripening by Diffusion


Solutions to Fick's Second Law: Infinite and Semi-Infinite Boundary Conditions


Goal and Caveats


Solution with a Dimensionless Variable: x2 = 4 Dt


Semi-Infinite BCs: Diffusion of B into Si and Error Functions


Infinite BCs: Interdiffusion of Cu and Ni


Constant Surface Concentration: B into Si


Constant Surface Concentration: Decarburizing Transformer Steel


General Solution


Appendix A: Integrating e x2dx ∞ − −∞ ∫


Appendix B: Notes on the Error Function


Finite Boundary Conditions


Coring in a Cast Alloy


Drying a Cast Polymer Sheet: C(x,0) = C0 sin (πx/L)


Degassing Transformer Steel: C(x,0) = C0


Diffusion through a Polymer Membrane


Equilibration by Diffusion in a Cell


Interdiffusion of Finite Size Particles


General Approximation: Dt/L2 ≅ 1


Diffusion in Non-Ideal Systems


Generalized Diffusion: Fluxes and Forces


Flux of Moving Particles


Mobility and Forces: Stokes Law


Particle Size Measurement by Settling


Electrical Mobility


Absolute Mobility and Diffusion


Diffusion in Liquids: Stokes-Einstein Equation


Ionic Conductivity: Nernst-Einstein Equation


Non-Ideal Diffusion Processes


Interdiffusion in Isomorphous Systems: Metals


Intrinsic Diffusion Coefficient


Kirkendall Effect


Darken's Equations


Interdiffusion in Isomorphous Systems: Ionic Compounds


Non-Isomorphous Systems


Free Energy Gradients and Geometries


Oxidation of Metals


Calcining: Linear Model


Calcining: Jander Model


Calcining: Braunstein Model


Sintering


Grain Growth


Spinodal Decomposition Revisited