Back to School Savings: Save up to 30% on print books and eBooks. No promo code needed.
Back to School Savings: Save up to 30%
Lectures on Theoretical Physics
Thermodynamics and Statistical Mechanics
1st Edition - January 1, 1964
Author: Arnold Sommerfeld
Editors: F. Bopp, J. Meixner, J. Kestin
9 7 8 - 0 - 3 2 3 - 1 3 7 7 3 - 7
Thermodynamics and Statistical Mechanics deals with the method of thermodynamic potentials, the four Gibbsian potentials, and Boltzmann's statistics. The book reviews the general… Read more
Save 50% on book bundles
Immediately download your ebook while waiting for your print delivery. No promo code is needed.
Thermodynamics and Statistical Mechanics deals with the method of thermodynamic potentials, the four Gibbsian potentials, and Boltzmann's statistics. The book reviews the general considerations of thermodynamics, such as the first and second laws of thermodynamics, the van der Waals equation, and Nernst's third law of thermodynamics. The text also discusses the application of thermodynamics to special systems, the theory of phase equilibria, the electromotive force of galvanic cells, and the thermodynamics of near-equilibrium processes. The book explains the equation of state of a perfect gas, the Maxwellian velocity distribution, and the statistical significance of the constants in van der Waal's equation. The text notes that the states of equilibrium can be treated in a simple manner compared to complex methods used in problems connected with irreversible processes. The book explains that the atoms in a molecule are capable of performing small vibrations about their position of equilibrium as they possess both kinetic and potential energy. The text also discusses the quantization of vibrational energy and rotational energy. The book can be helpful for students of physics, thermodynamics, and related subjects. It can also be used by instructors in advanced physics.
Author’s PrefaceEditor’s PrefaceTranslator’s PrefaceChapter I. Thermodynamics. General Considerations 1. Temperature as a Property of a System 2. Work and Heat 3. The Perfect Gas A. Boyle’s Law (The Law of Boyle and Mariotte) B. Charles’ Law (The Law of Gay-Lussac) C. Avogadro’s Law and the Universal Gas Constant 4. The First Law. Energy and Enthalpy as Properties A. Equivalence of Heat and Work B. The Enthalpy as a Property C. Digression on the Ratio of Specific Heats cp and cv 5. The Reversible and the Irreversible Adiabatic Process A. The Reversible Adiabatic Process B. The Irreversible Adiabatic Process C. The Joule-Kelvin Porous Plug Experiment D. A Conclusion of Great Consequence 6. The Second Law A. The Carnot Cycle and Its Efficiency B. The First Part of the Second Law C. The Second Part of the Second Law D. Simplest Numerical Examples E. Remarks on the Literature of the Second Law F. On the Relative Rank of Energy and Entropy 7. The Thermodynamic Potentials and the Reciprocity Relations 8. Thermodynamic Equilibria A. Unconstrained Thermodynamic Equilibrium and Maximum of Entropy B. An Isothermal and Isobaric System in Unconstrained Thermodynamic Equilibrium C. Additional Degrees of Freedom in Retarded Equilibrium D. Extremum Properties of the Thermodynamic Potentials E. The Theorem on Maximum Work 9. The van der Waals Equation A. Course of Isotherms B. Entropy and the Caloric Behavior of the van der Waals Gas 10. Remarks on the Liquefaction of Gases According to van der Waals A. The Integral and the Differential Joule-Thomson Effect B. The Inversion Curve and Its Practical Utilization C. The Boundary of the Region of Co-existing Liquid-Vapor Phases in the p, v Plane 11. The Kelvin Temperature Scale 12. Nernst’s Third Law of ThermodynamicsChapter II. The Application of Thermodynamics to Special Systems 13. Gaseous Mixtures. Gibbs’ Paradox. The Law Due to Guldberg and Waage A. Reversible Separation of Gases B. The Increase in Entropy During Diffusion and Gibbs’ Paradox C. The Law of Mass Action Due to Guldberg and Waage 14. Chemical Potentials and Chemical Constants A. The Chemical Potentials μi B. Relation Between the μi’s and the gi's for Ideal Mixtures C. The Chemical Constant of a Perfect Gas 15. Dilute Solutions A. General and Historical Remarks B. Van 't Hoff’s Equation of State for Dilute Solutions 16. The Different Phases of Water. Remarks on the Theory of the Steam Engine A. The Vapor-Pressure Curve and Clapeyron’s Equation B. Phase Equilibrium Between Ice and Water C. The Specific Heat of Saturated Steam 17. General Remarks on the Theory of Phase Equilibria A. The Triple Point of Water B. Gibbs’ Phase Rule C. Raoult’s Laws for Dilute Solutions D. Henry’s Law of Absorption (1803) 18. The Electromotive Force of Galvanic Cells A. Electrochemical Potentials B. The Daniell Cell, 1836 C. Contraction of Individual Reactions into a Simplified Overall Reaction D. The Gibbs-Helmholtz Fundamental Equation E. Numerical Example F. Remarks on the Integration of the Fundamental Equation 19. Ferro- and Paramagnetism A. Work of Magnetization and Magnetic Equation of State B. Langevin’s Equation for Paramagnetic Substances C. The Theory of Ferromagnetic Phenomena Due to Weiss D. The Specific Heats cH and cM E. The Magneto-Caloric Effect 20. Black Body Radiation A. Kirchhoff’s Law B. The Stefan-Boltzmann Law C. Wien’s Law D. Planck’s Law of Radiation 21. Irreversible Processes. Thermodynamics of Near-Equilibrium Processes A. Conduction of Heat and Local Entropy Generation B. The Conduction of Heat in an Anisotropic Body and Onsager’s Reciprocal Relations C. Thermoelectric Phenomena D. Internal Transformations E. General Relations F. Limitations of the Thermodynamic Theory of Irreversible ProcessesChapter III. The Elementary Kinetic Theory of Gases 22. The Equation of State of a Perfect Gas 23. The Maxwellian Velocity Distribution A. The Maxwellian Distribution for a Monatomic Gas. Proof of 1860 B. Numerical Values and Experimental Results C. General Remarks on the Energy Distribution. The Boltzmann Factor 24. Brownian Motion 25. Statistical Considerations on Paramagnetic Substances A. The Classical Langevin Function B. Modification of Langevin’s Function with the Aid of Quantum Mechanics 26. The Statistical Significance of the Constants in van der Waals’ Equation A. The Volume of a Molecule and the Constant b B. The van der Waals Cohesion Forces and the Constant a 27. The Problem of the Mean Free Path A. Calculation of the Mean Free Path in One Special Case B. Viscosity C. Thermal Conductivity D. Some General Remarks on the Problems Associated with the ConceptChapter IV. General Statistical Mechanics: Combinatorial Method 28. Liouville’s Theorem, T-space and μ- space A. The Multidimensional T-space (Phase Space) B. Liouville’s Theorem C. Equality of Probability for the Perfect Gas 29. Boltzmann’s Principle A. Permutability as a Measure of the Probability of a State B. The Maximum of Probability as a Measure of Entropy C. The Combining of Elementary Cells 30. Comparison with Thermodynamics A. Constant Volume Process B. General Process Performed by a Gas in the Absence of External Forces C. A Gas in a Field of Forces; the Boltzmann Factor D. The Maxwell-Boltzmann Velocity Distribution Law E. Gaseous Mixtures 31. Specific Heat and Energy of Rigid Molecules A. The Monatomic Gas B. Gas Composed of Diatomic Molecules C. The Polyatomic Gas and Kelvin's Clouds 32. The Specific Heat of Vibrating Molecules and of Solid Bodies A. The Diatomic Molecule B. Polyatomic Gases C. The Solid Body and the Dulong-Petit Rule 33. The Quantization of Vibrational Energy A. The Linear Oscillator B. The Solid Body C. Generalization to Arbitrary Quantum States 34. The Quantization of Rotational Energy 35. Supplement to the Theory of Radiation and to that of Solid Bodies A. Method of Natural Vibrations B. Debye’s Theory of the Specific Heat of a Solid 36. Partition Function in the T-space A. The Gibbs Condition B. Connection with Boltzmann’s Method C. Correction for Quantum Effects D. Analysis of Gibbs’ Hypothesis 37. Fundamentals of Quantum Statistics A. Quantum Statistics of Identical Particles B. The Method Due to Darwin and Fowler C. Bose-Einstein and Fermi-Dirac Statistics D. The Saddle-Point Method 38. Degenerate Gases A. Bose-Einstein and Fermi-Dirac Distribution B. Degree of Gas Degeneration C. Highly Degenerate Bose-Einstein Gas 39. Electron Gas in Metals A. Introductory Remark to Drude’s Method B. The Completely Degenerate Fermi-Dirac Gas C. Almost Complete Degeneracy D. Special Problems 40. The Mean Square of FluctuationsChapter V. Outline of an Exact Kinetic Theory of Gases 41. The Maxwell-Boltzmann Collision Equation A. Description of a State in the Kinetic Theory of Gases B. The Variation of f with Time C. The Laws of Elastic Collision D. Boltzmann’s Collision Integral E. Boltzmann’s Hypothesis About Molecular Chaos 42. The H-Theorem and Maxwellian Distribution A. The H-Theorem B. Maxwellian Distribution C. Equilibrium Distributions 43. Fundamental Equations of Fluid Dynamics A. Series Expansion for the Distribution Function B. Maxwell’s Transport Equation C. Conservation of Mass D. Conservation of Momentum E. Conservation of Energy F. Entropy Theorem 44. On the Integration of the Collision Equation A. Integration with the Aid of Moment Equations B. Transformation of the Equations for Moments C. Evaluation of Collision Moments D. Viscosity and Thermal Conductivity 45. Conductivity and the Wiedemann-Franz Law A. The Collision and Transfer Equations for Electrons in Metals B. Approximate Solution of the Collision Equation C. Flux of Current and Energy D. Ohm’s Law E. Thermal Conductivity and Absolute Thermal Electromotive Force F. The Wiedemann-Franz LawProblems for Chapter IProblems for Chapter IIProblems for Chapter IIIProblems for Chapter IVProblems for Chapter VHints for the Solution of ProblemsIndex