Synopses & Reviews
Building on the Maxwell-Boltzmann method of step-by-step development of the subject, this book makes few presumptions concerning students' previous exposure to statistics, quantum mechanics, or spectroscopy. The book begins with the fundamentals of statistical thermodynamics, pauses to recover needed knowledge from quantum mechanics and spectroscopy, and then moves on to applications involving ideal gases, the solid state, and radiation. A full introduction to kinetic theory is provided, including its applications to transport phenomena and chemical kinetics. Modern applications, such as laser-based diagnostics, are also discussed.
Synopsis
This textbook discusses the fundamentals and applications of statistical thermodynamics for beginning graduate students in engineering and the physical sciences.
Synopsis
Statistical Thermodynamics: Fundamentals and Applications discusses the fundamentals and applications of statistical thermodynamics for beginning graduate students in the engineering sciences. This book features a step-by-step development of the subject with few presumptions concerning previous exposure of students to statistics, quantum mechanics or spectroscopy. Each chapter is carefully written to address student difficulties in learning this challenging subject, which is fundamental to combustion, propulsion, transport phenomena, spectroscopic measurements and nanotechnology. Students are made comfortable with their new knowledge by the inclusion of both example and prompted homework problems.
About the Author
Normand M. Laurendeau is the Ralph and Bettye Bailey Professor of Combustion at Purdue University. He teaches at both the undergraduate and graduate levels in the areas of thermodynamics, combustion and engineering ethics. He conducts research in the combustion sciences, with particular emphasis on laser diagnostics, pollutant formation and flame structure. Dr Laurendeau is well known for his pioneering research on the development and application of both nanosecond and picosecond laser-induced fluorescence strategies to quantitative species concentration measurements in laminar and turbulent flames. He has authored or coauthored over 150 publications in the archival scientific and engineering literature. Professor Laurendeau is a Fellow of the American Society of Mechanical Engineers and a member of the Editorial Advisory Board for the peer-reviewed journal Combustion Science and Technology.
Table of Contents
Preface; 1. Introduction; Part I. Fundamentals of Statistical Thermodynamics: 2. Probability and statistics; Problem set I. Probability theory and statistical mathematics; 3. The statistics of independent particles; 4. Thermodynamics properties in the dilute limit; Problem set II. Statistical modeling for thermodynamics; Part II. Quantum Mechanics and Spectroscopy: 5. Basics of quantum mechanics; 6. Quantum analysis of internal energy modes; 7. The spectroscopy of diatomic molecules; Problem set III. Quantum mechanics and spectroscopy; Part III. Statistical Thermodynamics in the Dilute Limit: 8. Interlude: from particle to assembly; 9. Thermodynamic properties of the ideal gas; Problem set IV. Thermodynamic properties of the ideal gas; 10. Statistical thermodynamics for ideal gas mixtures; 11. Concentration and temperature measurements; Problem set V. Chemical equilibrium and diagnostics; Part IV. Statistical Thermodynamics Beyond the Dilute Limit: 12. Thermodynamics and information; 13. Elements of the solid state; 14. Equilibrium radiation; Problem set VI. The solid state and radiation; Part V. Non-Equilibrium Statistical Thermodynamics: 15. Elementary kinetic theory; 16. Kinetics of molecular transport; 17. Chemical kinetics; Problem set VII. Kinetic theory and molecular transport; Part VI. The Ensemble Method of Statistical Thermodynamics: 18. The canonical and grand canonical ensembles; 19. Applications of ensemble theory to real gases; Problem set VIII. Ensemble theory and the non-ideal gas; 20. Whence and whither; Part VII. Appendices; Index.