Statistical Physics : Volume 5

What Landau does here, and which in explicably very few Statistical Mechanics books do nowadays, is the full Gibbs Formalism. Not only is the Gibbs Formalism more compatible with Quantum Mechanics, it can also fits in beautifully with Ensemble Statistics and Inofrmation Theory. More over, it is at once clear Maxwell and Boltzmann statistics are only special cases of the Gibbs formalism, and can be easily shown in a few lines.

What Landau does, is to gave an elegant and cohesive view the trully fundamental features of Statistical Mechanics. Chapters 1-6 of this book alone displays a deeper level of understanding than whole books that have been written. If you are interested in Statistical Mechanics at all, this must be a centerpiece of your library.

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Summary: This is the most beautiful book on statistical mechanics
Review: This is the first volume of the Statistical Physics of Landau, Lifshitz. It's, of course, an extraordinary book, coming from these authors. The book starts with a chapter which defines entropy and derives its main properties. Then comes a masterly chapter on Thermodynamics where the criterion for equillibrium is that the entropy be maximum. The things they derive from that! Now and then I like to reread this chapter just for fun! After that statistical mechanics of equillibrium is constructed along the lines of Gibbs, starting from the microcanonical distribution, wherefrom the others are derived. Applications then start. Thermodynamical equillibrium in General Relativity is treated, as is gravitational collapse of stars. Chemical equillibrium is wonderfully done, being applied also for relativistic reactions among elementary particles, as neutrinos. There is no other book even close to this, as physics is concerned.

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Summary: THE BEST BOOK ON STATISTICAL PHYSICS
Review: This is the Volume 5 of the famous Course of Theoretical Physics by L. D. Landau and E. M. Lifshitz. All serious students of theoretical physics must possess the ten volumes of this excellent Course, which cover in detail and rigour practically all the branches of theoretical physics. The Volume 5 treats the subject of classical and quantum statistics. It contains an unusual approach of these subjects, based on the general Gibbs method, avoiding the introduction of ergodic hypotheses and, in the case of the ideal gas, of "a priori" probabilities, which are difficult to justify and serves only to obscure the exposition. The book is complete and contains chapters not usually found in other similar books, such as the chapter on second-order phase transitions. The clarity of exposition and rigour is notorious in this book. A magnific book!

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Summary: A UNIQUE BOOK ON MODERN STATISTICAL PHYSICS
Review: This is the Volume 9 of the famous Course of Theoretical Physics by L. D. Landau and E. M. Lifshitz. All serious students of theoretical physics must possess the ten volumes of this excellente Course, which cover in detail and rigour practically all the branches of theoretical physics. The Volume 9 treats important specialized topics of modern statistical physics. These topics include the theory of quantum liquids(Fermi and Bose types), the theory of superfluidity, created by Landau to account for the phenomena ocurring in liquid helium at approximately 2 kelvin, the microscopic theory of superconductivity, the general method of Green's functions, so important to modern statistical physics, and some other topics, such as the quantum mechanics of a electron in a crystal lattice. The book still contains the general theory of electromagnetic and hydrodynamic fluctuations, treated in the spirit of the Green's functions. These topics are treated with rigour, efficiency and c! larity of language. For this reason, all readers with some aqquaintance with basic statistical physics can read and understand much of this book without major problems. Certainly there is not other book comparable with the Volume 9, a unique and valuable addition to the literature on modern statistical physics!

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Summary: Green's functions, superfluids, superconductors, magnetism
Review: This review is for Volume 9 of the Landau Course of Theoretical Physics.

The whole Course is clear and concise, so it makes sense for anyone who wants to do theoretical physics to go through all ten volumes.

We start off with normal Fermi liquids and gases, including a nice discussion of Zero Sound (which is distinguished from normal sound mostly by a slight increase in the sound velocity as one gets colder than a transition temperature, and by increased absorption of sound near the transition temperature). Then we learn about Green's functions in a Fermi system at T = 0 and Feynman diagram representations of them.

After that, we study Bose liquids and gases. That means the properties of superfluids, including quasi-particles (phonons and rotons) and quantized vortex filaments. And the book shows how to apply Green's functions to Bose liquids. There's an interesting section on the disintegration of quasi-particles. Next, we're introduced to Green's functions for T > 0, using the Matsubara operators to reduce the complexity of the diagrams.

And then we're ready to learn about superconductors. That means learning about Cooper pairing and superfluid Fermi gases, and learning how to apply Green's functions to them. And, not surprisingly, we learn the Ginzburg-Landau equations, so that we can determine the behavior of superconductors in magnetic fields in temperature ranges near the transition point.

There's also a chapter on electrons in the crystal lattice, including the de Hass-van Alphen effect (which refers to a metal's magnetic susceptibility oscillating as the strength of a strong magnetic field changes - due to the quantization of the energy levels of the electrons) and electron-phonon interactions. And there's a nice chapter on magnetism.

In the preface, the authors state "we must again stress that this book is part of a course of theoretical physics and in no way attempts to be a textbook of solid state theory." Are they kidding? This course is an excellent way to learn solid state physics.