The last 5 chapters treat topics of recent interest to researchers, including: the Ising and Potts models, spin waves in ferromagnetic and anti-ferromagnetic media, sound propagation in non-ideal gases and the decay of sound waves, introduction to the understanding of glasses and spin glasses, superfluidity and superconductivity.
The selection of material is wide-ranging and the mathematics for handling it completely self-contained, ranging from counting (probability theory) to quantum field theory as used in the study of fermions, bosons and as an adjunct in the solutions of the equations of classical diffusion-reaction theory. In addition to the standard material found in most recent books on statistical physics the constellation of topics covered in this text includes numerous original items:
· Generalization of "negative temperature" to interacting spins · Derivation of Gibbs' factor from first principles · Exact free energy of interacting particles in 1D (e.g., classical and quantum Tonk's gas) · Introduction to virial expansions, Equations of State, Correlation Functions and "critical exponents" · Superfluidity in ideal and non-ideal fluids (both Bogolubov and Feynman theories) · Superconductivity: thermodynamical approach and the BCS theory · Derivation of "Central Limit Theorem" and its applications · Boltzmann's "H-Theorem" and the nonlinear Boltzmann equation · Exact solution of nonlinear Boltzmann Equation for electrons in time-dependent electric field and the derivation of Joule heating, transport parameters in crossed electric and magnetic fields, etc. · Frequency spectrum and decay of sound waves in gases · Exact evaluation of free energy and thermodynamic properties of the two-dimensional Ising model in regular and fully frustrated (spin-glass like) lattices · The "zipper" model of crystal fracture or polymer coagulation - calculation of Tc · Potts model in 2D: duality and Tc · "Doi's theory" of diffusion-limited chemical reactions with some exact results — including the evaluation of statistical fluctuations in radioactive decay · Thermodynamic Green Functions and their applications to fermions and bosons with an example drawn from random matrix theory
and much more.