| Preface | p. xv |
| Introduction | p. 1 |
| The Statistical Foundation of Classical Thermodynamics | p. 1 |
| A Classification Scheme for Statistical Thermodynamics | p. 3 |
| Why Statistical Thermodynamics? | p. 3 |
| Fundamentals of Statistical Thermodynamics | |
| Probability and Statistics | p. 7 |
| Probability: Definitions and Basic Concepts | p. 7 |
| Permutations and Combinations | p. 10 |
| Probability Distributions: Discrete and Continuous | p. 11 |
| The Binomial Distribution | p. 13 |
| The Poisson Distribution | p. 15 |
| The Gaussian Distribution | p. 16 |
| Combinatorial Analysis for Statistical Thermodynamics | p. 18 |
| Distinguishable Objects | p. 19 |
| Indistinguishable Objects | p. 20 |
| Probability Theory and Statistical Mathematics (Chapter 2) | p. 23 |
| The Statistics of Independent Particles | p. 29 |
| Essential Concepts from Quantum Mechanics | p. 30 |
| The Ensemble Method of Statistical Thermodynamics | p. 31 |
| The Two Basic Postulates of Statistical Thermodynamics | p. 32 |
| The M-B Method: System Constraints and Particle Distribution | p. 33 |
| The M-B Method: Microstates and Macrostates | p. 33 |
| The Most Probable Macrostate | p. 35 |
| Bose-Einstein and Fermi-Dirac Statistics | p. 37 |
| Bose-Einstein Statistics | p. 37 |
| Fermi-Dirac Statistics | p. 38 |
| The Most Probable Particle Distribution | p. 39 |
| Entropy and the Equilibrium Particle Distribution | p. 40 |
| The Boltzmann Relation for Entropy | p. 40 |
| Identification of Lagrange Multipliers | p. 41 |
| The Equilibrium Particle Distribution | p. 42 |
| Thermodynamic Properties in the Dilute Limit | p. 45 |
| The Dilute Limit | p. 45 |
| Corrected Maxwell-Boltzmann Statistics | p. 46 |
| The Molecular Partition Function | p. 47 |
| The Influence of Temperature | p. 49 |
| Criterion for Dilute Limit | p. 50 |
| Internal Energy and Entropy in the Dilute Limit | p. 51 |
| Additional Thermodynamic Properties in the Dilute Limit | p. 53 |
| The Zero of Energy and Thermodynamic Properties | p. 55 |
| Intensive Thermodynamic Properties for the Ideal Gas | p. 56 |
| Statistical Modeling for Thermodynamics (Chapters 3-4) | p. 59 |
| Quantum Mechanics and Spectroscopy | |
| Basics of Quantum Mechanics | p. 69 |
| Historical Survey of Quantum Mechanics | p. 69 |
| The Bohr Model for the Spectrum of Atomic Hydrogen | p. 72 |
| The de Broglie Hypothesis | p. 76 |
| A Heuristic Introduction to the Schrodinger Equation | p. 78 |
| The Postulates of Quantum Mechanics | p. 80 |
| The Steady-State Schrodinger Equation | p. 83 |
| Single-Particle Analysis | p. 84 |
| Multiparticle Analysis | p. 85 |
| The Particle in a Box | p. 86 |
| The Uncertainty Principle | p. 90 |
| Indistinguishability and Symmetry | p. 92 |
| The Pauli Exclusion Principle | p. 94 |
| The Correspondence Principle | p. 95 |
| Quantum Analysis of Internal Energy Modes | p. 97 |
| Schrodinger Wave Equation for Two-Particle System | p. 97 |
| Conversion to Center-of-Mass Coordinates | p. 98 |
| Separation of External from Internal Modes | p. 99 |
| The Internal Motion for a Two-Particle System | p. 99 |
| The Rotational Energy Mode for a Diatomic Molecule | p. 100 |
| The Vibrational Energy Mode for a Diatomic Molecule | p. 104 |
| The Electronic Energy Mode for Atomic Hydrogen | p. 108 |
| The Electronic Energy Mode for Multielectron Species | p. 115 |
| Electron Configuration for Multielectron Atoms | p. 116 |
| Spectroscopic Term Symbols for Multielectron Atoms | p. 118 |
| Electronic Energy Levels and Degeneracies for Atoms | p. 119 |
| Electronic Energy Levels and Degeneracies for Diatomic Molecules | p. 121 |
| Combined Energy Modes for Atoms and Diatomic Molecules | p. 123 |
| Selection Rules for Atoms and Molecules | p. 124 |
| The Spectroscopy of Diatomic Molecules | p. 129 |
| Rotational Spectroscopy Using the Rigid-Rotor Model | p. 130 |
| Vibrational Spectroscopy Using the Harmonic-Oscillator Model | p. 131 |
| Rovibrational Spectroscopy: The Simplex Model | p. 132 |
| The Complex Model for Combined Rotation and Vibration | p. 136 |
| Rovibrational Spectroscopy: The Complex Model | p. 138 |
| Electronic Spectroscopy | p. 141 |
| Energy-Mode Parameters for Diatomic Molecules | p. 144 |
| Quantum Mechanics and Spectroscopy (Chapters 5-7) | p. 147 |
| Statistical Thermodynamics in the Dilute Limit | |
| Interlude: From Particle to Assembly | p. 157 |
| Energy and Degeneracy | p. 157 |
| Separation of Energy Modes | p. 159 |
| The Molecular Internal Energy | p. 160 |
| The Partition Function and Thermodynamic Properties | p. 161 |
| Energy-Mode Contributions in Classical Mechanics | p. 163 |
| The Phase Integral | p. 164 |
| The Equipartition Principle | p. 166 |
| Mode Contributions | p. 167 |
| Thermodynamic Properties of the Ideal Gas | p. 169 |
| The Monatomic Gas | p. 169 |
| Translational Mode | p. 169 |
| Electronic Mode | p. 173 |
| The Diatomic Gas | p. 175 |
| Translational and Electronic Modes | p. 176 |
| The Zero of Energy | p. 176 |
| Rotational Mode | p. 178 |
| Quantum Origin of Rotational Symmetry Factor | p. 182 |
| Vibrational Mode | p. 184 |
| Rigorous and Semirigorous Models for the Diatomic Gas | p. 187 |
| The Polyatomic Gas | p. 192 |
| Rotational Contribution | p. 194 |
| Vibrational Contribution | p. 196 |
| Property Calculations for Polyatomic Molecules | p. 198 |
| Thermodynamic Properties of the Ideal Gas (Chapters 8-9) | p. 201 |
| Statistical Thermodynamics for Ideal Gas Mixtures | p. 205 |
| Equilibrium Particle Distribution for the Ideal Gas Mixture | p. 205 |
| Thermodynamic Properties of the Ideal Gas Mixture | p. 208 |
| The Reacting Ideal Gas Mixture | p. 211 |
| Equilibrium Particle Distribution for Reactive Ideal Gas Mixture | p. 211 |
| Equilibrium Constant: Introduction and Development | p. 213 |
| Equilibrium Constant: General Expression and Specific Examples | p. 214 |
| Dissociation of a Homonuclear Diatomic | p. 217 |
| The Homonuclear-Heteronuclear Conversion Reaction | p. 219 |
| The Ionization Reaction | p. 220 |
| Concentration and Temperature Measurements | p. 223 |
| Mode Temperatures | p. 224 |
| Radiative Transitions | p. 225 |
| Spectral Transfer of Radiation | p. 227 |
| The Einstein Coefficients | p. 228 |
| Line Broadening | p. 229 |
| Absorption Spectroscopy | p. 230 |
| Emission Spectroscopy | p. 234 |
| Emissive Diagnostics | p. 234 |
| The Problem of Self-Absorption | p. 235 |
| Fluorescence Spectroscopy | p. 237 |
| Sodium D-Line Reversal | p. 240 |
| Advanced Diagnostic Techniques | p. 241 |
| Chemical Equilibrium and Diagnostics (Chapters 10-11) | p. 243 |
| Statistical Thermodynamics Beyond the Dilute Limit | |
| Thermodynamics and Information | p. 251 |
| Reversible Work and Heat | p. 251 |
| The Second Law of Thermodynamics | p. 252 |
| The Boltzmann Definition of Entropy | p. 253 |
| Information Theory | p. 254 |
| Spray Size Distribution from Information Theory | p. 256 |
| Elements of the Solid State | p. 259 |
| Statistical Thermodynamics of the Crystalline Solid | p. 259 |
| Einstein Theory for the Crystalline Solid | p. 262 |
| Debye Theory for the Crystalline Solid | p. 263 |
| Critical Evaluation of the Debye Formulation | p. 266 |
| The Band Theory of Metallic Solids | p. 268 |
| Thermodynamic Properties of the Electron Gas | p. 270 |
| The Metallic Crystal near Absolute Zero | p. 273 |
| Equilibrium Radiation | p. 275 |
| Bose-Einstein Statistics for the Photon Gas | p. 275 |
| Photon Quantum States | p. 276 |
| The Planck Distribution Law | p. 276 |
| Thermodynamics of Blackbody Radiation | p. 278 |
| The Influence of Wavelength for the Planck Distribution | p. 280 |
| The Solid State and Radiation (Chapters 13-14) | p. 283 |
| Nonequilibrium Statistical Thermodynamics | |
| Elementary Kinetic Theory | p. 289 |
| The Maxwell-Boltzmann Velocity Distribution | p. 289 |
| The Maxwell-Boltzmann Speed Distribution | p. 291 |
| The Maxwell-Boltzmann Energy Distribution | p. 294 |
| Molecular Effusion | p. 295 |
| The Ideal Gas Pressure | p. 298 |
| Kinetics of Molecular Transport | p. 301 |
| Binary Collision Theory | p. 301 |
| Fundamentals of Molecular Transport | p. 305 |
| The Mean Free Path | p. 305 |
| The Molecular Flux | p. 307 |
| Transport Properties | p. 309 |
| Rigorous Transport Theory | p. 311 |
| Dimensionless Transport Parameters | p. 312 |
| Collision Integrals | p. 313 |
| The Lennard-Jones Potential | p. 314 |
| Rigorous Expressions for Transport Properties | p. 316 |
| Chemical Kinetics | p. 319 |
| The Bimolecular Reaction | p. 319 |
| The Rate of Bimolecular Reactions | p. 320 |
| Chemical Kinetics from Collision Theory | p. 321 |
| The Significance of Internal Energy Modes | p. 324 |
| Chemical Kinetics from Transition State Theory | p. 325 |
| Kinetic Theory and Molecular Transport (Chapters 15-17) | p. 331 |
| The Ensemble Method of Statistical Thermodynamics | |
| The Canonical and Grand Canonical Ensembles | p. 339 |
| The Ensemble Method | p. 339 |
| The Canonical Ensemble | p. 340 |
| The Equilibrium Distribution for the Canonical Ensemble | p. 341 |
| Equilibrium Properties for the Canonical Ensemble | p. 342 |
| Independent Particles in the Dilute Limit | p. 345 |
| Fluctuations in Internal Energy | p. 347 |
| Grand Canonical Ensemble | p. 349 |
| The Equilibrium Distribution for the Grand Canonical Ensemble | p. 351 |
| Equilibrium Properties for the Grand Canonical Ensemble | p. 352 |
| Independent Particles in the Dilute Limit Revisited | p. 355 |
| Applications of Ensemble Theory to Real Gases | p. 359 |
| The Behavior of Real Gases | p. 359 |
| Equation of State for Real Gases | p. 360 |
| Canonical Partition Function for Real Gases | p. 361 |
| The Virial Equation of State | p. 362 |
| The Second Virial Coefficient | p. 364 |
| Rigid-Sphere and Square-Well Potentials | p. 366 |
| Implementation of Lennard-Jones Potential | p. 367 |
| The Third Virial Coefficient | p. 369 |
| Properties for Real Gases | p. 371 |
| p. 375 |
| Whence and Whither | p. 379 |
| Reprising the Journey | p. 379 |
| Preparing for New Journeys | p. 383 |
| The Continuing Challenge of Thermodynamics | p. 385 |
| Appendices | |
| Physical Constants and Conversion Factors | p. 389 |
| Series and Integrals | p. 390 |
| Periodic Table | p. 391 |
| Mathematical Procedures | p. 393 |
| Thermochemical Data for Ideal Gases | p. 396 |
| Summary of Classical Thermodynamics | p. 409 |
| Review of Classical Mechanics | p. 415 |
| Review of Operator Theory | p. 418 |
| The Spherical Coordinate System | p. 421 |
| Electronic Energy Levels | p. 424 |
| Energy-Mode Parameters for Molecules | p. 427 |
| Normal Mode Analysis | p. 430 |
| Tabulation of Debye Function | p. 433 |
| Maxwell-Boltzmann Energy Distribution | p. 434 |
| Force Constants for the Lennard-Jones Potential | p. 436 |
| Collision Integrals for Calculating Transport Properties from the Lennard-Jones Potential | p. 437 |
| Reduced Second Virial Coefficient from the Lennard-Jones Potential | p. 438 |
| References and Acknowledgments | p. 439 |
| Index | p. 445 |
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