An updated and expanded translation of the highly popular Russian textbook, Introduction to Thermodynamics and Kinetic Theory of Matter examines equilibrium and kinetic properties of matter--gas, liquid, and solid--using the general principles of thermodynamics and kinetic theory. Readable and accessible throughout, this book provides both thermodynamic and statistical points of view, covering thermodynamic potentials, such as entropy and free energy, whenever relevant.

The book takes a fresh approach to its subject matter, focusing equally on condensed matter and gases. It compares rarefied and condensed matter, classical and quantum systems, and real and ideal gases. Central to the book are intermolecular interactions, and the process by which they lead matter into a change of state. The author discusses the solid, crystalline phase, showing how it can be manipulated by lattice vibration as well as by thermal pressure. In addition, this is the only book in which the quasi-thermodynamic theory of gas/liquid interface is used for density profile calculation within the van der Waals theory of surface tension.

Another major theme investigated here is the irreversible transfer properties of matter, such as diffusion and viscosity, heat and electric conductivity. The book presents the hypothesis of "local equilibrium, " which facilitates the calculation of the fluxes of matter, heat, or charge-- comparing them and predicting the resultant density and temperature dependencies of transport coefficients. Examples from situations when local equilibrium is absent are also included.

Finally, the book covers all reversible processes subject to the principles of thermodynamics. This isespecially useful in experimental applications--optimizing the work of heat engines and pumps; providing methods for the condensation of gases into liquids; and explaining various phenomena such as phase equilibrium and transitions, surface tension, and thermal radiation.

Addressing a broad audience, and using inductive logic and many illustrations, Introduction to Thermodynamics and Kinetic Theory of Matter leads the reader from basic phenomena to advanced models, and provides from the outset opportunities for experimental work in related fields of physics and physical chemistry.

This highly original book about the kinetic properties of the microparticles constituting gases, liquids, and solids--as well as light--is an updated version of a very popular Russian text. Dealing with areas of molecular physics, this edition updates all information, covering elementary statistical mechanics and kinetic theory, and expanding the Russian text to include thermodynamics.

Particularly innovative are the methods--exclusive to this book--for calculating surface structure within quasi-thermodynamics. Also unique is the comparison between rarefied and condensed matter, which is not offered in any other text.

Addressing both students and advanced researchers, the book assumes only a general math and classical mechanics background, allowing the reader to progress quickly from the introductory material to complex topics. It provides:

• Rigorous quantitative treatment of all phenomena, useful for starting experiments in related fields of physics and physical chemistry
• Comprehensive coverage of molecular and photon gases, liquids and solids-- for students and faculty in physics
• Aunique treatment of solid and liquid equations of state--for researchers in thermophysics and physical chemistry
• 150 illustrations and references on experimental data for equations of state, orthometric curves, the knots of compressibility factor isotherms, as well as liquid-gas interface
• Several of the author's own original results
• An extensive list of suggested readings for both fundamental and in-depth study

Spectroscopic studies can reveal a wealth of information about the rotational and vibrational behavior of the constituent molecules of gases and liquids. This book reviews the fundamental concepts and models that underpin such studies. Throughout, discussion of the various quantum mechanical and semiclassical theories is interwoven with analysis of experimental results.

Spectroscopic studies can reveal a wealth of information about the rotational and vibrational behaviour of the constituent molecules of gases and liquids. This 1994 book reviews the fundamental concepts and important models which underpin such studies, dealing in particular with the phenomenon of spectral collapse, which accompanies the transition from rare gas to dense liquid. Throughout, discussion of the various quantum mechanical and semiclassical theories is interwoven with analysis of experimental results. These include data from optical, NMR, ESR and acoustic investigations. The book concludes with a discussion of the latest theories describing the mechanism of rotational diffusion in liquid solutions. This comprehensive review of theoretical models and techniques will be invaluable to graduate students and researchers interested in molecular dynamics and spectroscopy.