Produktbild: An Introduction to Applied Statistical Thermodynamics

An Introduction to Applied Statistical Thermodynamics

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Beschreibung

Produktdetails

Einband

Taschenbuch

Erscheinungsdatum

16.11.2010

Verlag

John Wiley & Sons Inc

Seitenzahl

368

Maße (L/B/H)

25.5/20.5/1.7 cm

Gewicht

669 g

Auflage

1. Auflage

Sprache

Englisch

ISBN

978-0-470-91347-5

Beschreibung

Produktdetails

Einband

Taschenbuch

Erscheinungsdatum

16.11.2010

Verlag

John Wiley & Sons Inc

Seitenzahl

368

Maße (L/B/H)

25.5/20.5/1.7 cm

Gewicht

669 g

Auflage

1. Auflage

Sprache

Englisch

ISBN

978-0-470-91347-5

Herstelleradresse

Libri GmbH
Europaallee 1
36244 Bad Hersfeld
DE

Email: GPSR Kontakt

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  • Produktbild: An Introduction to Applied Statistical Thermodynamics
  • PREFACE FOR INSTRUCTORS v
    PREFACE FOR STUDENTS ix

    CHAPTER 1 INTRODUCTION TO STATISTICAL THERMODYNAMICS 1
    1.1 Probabilistic Description 1
    1.2 Macroscopic States and Microscopic States 2
    1.3 Quantum Mechanical Description of Microstates 3
    1.4 The Postulates of Statistical Mechanics 5
    1.5 The Boltzmann Energy Distribution 6

    CHAPTER 2 THE CANONICAL PARTITION FUNCTION 9
    2.1 Some Properties of the Canonical Partition Function 9
    2.2 Relationship of the Canonical Partition Function to Thermodynamic Properties 11
    2.3 Canonical Partition Function for a Molecule with Several Independent Energy Modes 12
    2.4 Canonical Partition Function for a Collection of Noninteracting Identical Atoms 13
    Chapter 2 Problems 15

    CHAPTER 3 THE IDEAL MONATOMIC GAS 16
    3.1 Canonical Partition Function for the Ideal Monatomic Gas 16
    3.2 Identification of ss as 1/kT 18
    3.3 General Relationships of the Canonical Partition Function to Other Thermodynamic Quantities 19
    3.4 The Thermodynamic Properties of the Ideal Monatomic Gas 22
    3.5 Energy Fluctuations in the Canonical Ensemble 29
    3.6 The Gibbs Entropy Equation 33
    3.7 Translational State Degeneracy 35
    3.8 Distinguishability, Indistinguishability, and the Gibbs' Paradox 37
    3.9 A Classical Mechanics-Quantum Mechanics Comparison: The Maxwell-Boltzmann Distribution of Velocities 39
    Chapter 3 Problems 42

    CHAPTER 4 THE IDEAL DIATOMIC AND POLYATOMIC GASES 44
    4.1 The Partition Function for an Ideal Diatomic Gas 44
    4.1a The Translational and Nuclear Partition Functions 45
    4.1b The Rotational Partition Function 45
    4.1c The Vibrational Partition Function 47
    4.1d The Electronic Partition Function 48
    4.2 The Thermodynamic Properties of the Ideal Diatomic Gas 49
    4.3 The Partition Function for an Ideal Polyatomic Gas 53
    4.4 The Thermodynamic Properties of an Ideal Polyatomic Gas 55
    4.5 The Heat Capacities of Ideal Gases 58
    4.6 Normal Mode Analysis: The Vibrations of a Linear Triatomic Molecule 59
    Chapter 4 Problems 62

    CHAPTER 5 CHEMICAL REACTIONS IN IDEAL GASES 64
    5.1 The Nonreacting Ideal Gas Mixture 64
    5.2 Partition Function of a Reacting Ideal Chemical Mixture 65
    5.3 Three Different Derivations of the Chemical Equilibrium Constant in an Ideal Gas Mixture 67
    5.4 Fluctuations in a Chemically Reacting System 70
    5.5 The Chemically Reacting Gas Mixture: The General Case 73
    5.6 Two Illustrations 80
    Appendix: The Binomial Expansion 83
    Chapter 5 Problems 85

    CHAPTER 6 OTHER PARTITION FUNCTIONS 87
    6.1 The Microcanonical Ensemble for a Pure Fluid 87
    6.2 The Grand Canonical Ensemble for a Pure Fluid 89
    6.3 The Isobaric-Isothermal Ensemble 92
    6.4 The Restricted Grand or Semi-Grand Canonical Ensemble 93
    6.5 Comments on the Use of Different Ensembles 94
    Chapter 6 Problems 96

    CHAPTER 7 INTERACTING MOLECULES IN A GAS 98
    7.1 The Configuration Integral 98
    7.2 Thermodynamic Properties from the Configuration Integral 100
    7.3 The Pairwise Additivity Assumption 101
    7.4 Mayer Cluster Function and Irreducible Integrals 102
    7.5 The Virial Equation of State 109
    7.6 Virial Equation of State for Polyatomic Molecules 114
    7.7 Thermodynamic Properties from the Virial Equation of State 116
    7.8 Derivation of Virial Coefficient Formulae from the Grand Canonical Ensemble 118
    7.9 Range of Applicability of the Virial Equation 123
    Chapter 7 Problems 124

    CHAPTER 8 INTERMOLECULAR POTENTIALS AND THE EVALUATION OF THE SECOND VIRIAL COEFFICIENT 125
    8.1 Interaction Potentials for Spherical Molecules 125
    8.2 The Second Virial Coefficient in a Mixture: Interaction Potentials Between Unlike Atoms 136
    8.3 Interaction Potentials for Multiatom, Nonspherical Molecules, Proteins, and Colloids 137
    8.4 Engineering Applications and Implications of the Virial Equation of State 140
    Chapter 8 Problems 144

    CHAPTER 9 MONATOMIC CRYSTALS 147
    9.1 The Einstein Model of a Crystal 147
    9.2 The Debye Model of a Crystal 150
    9.3 Test of the Einstein and Debye Heat Capacity Models for a Crystal 157
    9.4 Sublimation Pressure and Enthalpy of Crystals 159
    9.5 A Comment on the Third Law of Thermodynamics 161
    Chapter 9 Problems 161

    CHAPTER 10 SIMPLE LATTICE MODELS FOR FLUIDS 163
    10.1 Introduction 164
    10.2 Development of Equations of State from Lattice Theory 165
    10.3 Activity Coefficient Models for Similar-Size Molecules from Lattice Theory 168
    10.4 The Flory-Huggins and Other Models for Polymer Systems 172
    10.5 The Ising Model 178
    Chapter 10 Problems 184

    CHAPTER 11 INTERACTING MOLECULES IN A DENSE FLUID. CONFIGURATIONAL DISTRIBUTION FUNCTIONS 185
    11.1 Reduced Spatial Probability Density Functions 185
    11.2 Thermodynamic Properties from the Pair Correlation Function 190
    11.3 The Pair Correlation Function (Radial Distribution Function) at Low Density 194
    11.4 Methods of Determination of the Pair Correlation Function at High Density 197
    11.5 Fluctuations in the Number of Particles and the Compressibility Equation 199
    11.6 Determination of the Radial Distribution Function of Fluids using Coherent X-ray or Neutron Diffraction 202
    11.7 Determination of the Radial Distribution Functions of Molecular Liquids 210
    11.8 Determination of the Coordination Number from the Radial Distribution Function 211
    11.9 Determination of the Radial Distribution Function of Colloids and Proteins 213
    Chapter 11 Problems 214

    CHAPTER 12 INTEGRAL EQUATION THEORIES FOR THE RADIAL DISTRIBUTION FUNCTION 216
    12.1 The Yvon-Born-Green (YBG) Equation 216
    12.2 The Kirkwood Superposition Approximation 219
    12.3 The Ornstein-Zernike Equation 220
    12.4 Closures for the Ornstein-Zernike Equation 222
    12.5 The Percus-Yevick Hard-Sphere Equation of State 227
    12.6 The Radial Distribution Functions and Thermodynamic Properties of Mixtures 228
    12.7 The Potential of Mean Force 230
    12.8 Osmotic Pressure and the Potential of Mean Force for Protein and Colloidal Solutions 237
    Chapter 12 Problems 239

    CHAPTER 13 DETERMINATION OF THE RADIAL DISTRIBUTION FUNCTION AND FLUID PROPERTIES BY COMPUTER SIMULATION 241
    13.1 Introduction to Molecular Level Computer Simulation 242
    13.2 Thermodynamic Properties from Molecular Simulation 245
    13.3 Monte Carlo Simulation 249
    13.4 Molecular-Dynamics Simulation 253
    Chapter 13 Problems 255

    CHAPTER 14 PERTURBATION THEORY 257
    14.1 Perturbation Theory for the Square-Well Potential 257
    14.2 First Order Barker-Henderson Perturbation Theory 262
    14.3 Second-Order Perturbation Theory 265
    14.4 Perturbation Theory Using Other Reference Potentials 269
    14.5 Engineering Applications of Perturbation Theory 272
    Chapter 14 Problems 274

    CHAPTER 15 A THEORY OF DILUTE ELECTROLYTE SOLUTIONS AND IONIZED GASES 276
    15.1 Solutions Containing Ions (and Electrons) 276
    15.2 Debye-Huckel Theory 280
    15.3 The Mean Ionic Activity Coefficient 291
    Chapter 15 Problems 296

    CHAPTER 16 THE DERIVATION OF THERMODYNAMIC MODELS FROM THE GENERALIZED VAN DER WAALS PARTITION FUNCTION 297
    16.1 The Statistical-Mechanical Background 298
    16.2 Application of the Generalized van der Waals Partition Function to Pure Fluids 301
    16.3 Equation of State for Mixtures from the Generalized van der Waals Partition Function 310
    16.4 Activity Coefficient Models from the Generalized van der Waals Partition Function 318
    16.5 Chain Molecules and Polymers 329
    16.6 Hydrogen-Bonding and Associating Fluids 332
    Chapter 16 Problems 334

    INDEX 335