scholarly journals PT symmetry in classical and quantum statistical mechanics

2013 ◽  
Vol 371 (1989) ◽  
pp. 20120058 ◽  
Author(s):  
Peter N. Meisinger ◽  
Michael C. Ogilvie
Keyword(s):  
Statistical Mechanics ◽  
Chemical Potential ◽  
Quantum Statistical Mechanics ◽  
Chiral Potts Model ◽  
Many Body ◽  
Natural Class ◽  
Symmetric Representation ◽  
Sign Problem ◽  
Dense Fluid ◽  
Complex Magnetic Field

-symmetric Hamiltonians and transfer matrices arise naturally in statistical mechanics. These classical and quantum models often require the use of complex or negative weights and thus fall outside the conventional equilibrium statistical mechanics of Hermitian systems. -symmetric models form a natural class where the partition function is necessarily real, but not necessarily positive. The correlation functions of these models display a much richer set of behaviours than Hermitian systems, displaying sinusoidally modulated exponential decay, as in a dense fluid, or even sinusoidal modulation without decay. Classical spin models with -symmetry include Z( N ) models with a complex magnetic field, the chiral Potts model and the anisotropic next-nearest-neighbour Ising model. Quantum many-body problems with a non-zero chemical potential have a natural -symmetric representation related to the sign problem. Two-dimensional quantum chromodynamics with heavy quarks at non-zero chemical potential can be solved by diagonalizing an appropriate -symmetric Hamiltonian.

QUASI-MODULAR SYMMETRY AND QUASI-HYPERGEOMETRIC FUNCTIONS IN QUANTUM STATISTICAL MECHANICS OF FRACTIONAL EXCLUSION STATISTICS

1999 ◽  
Vol 13 (29n30) ◽  
pp. 1039-1046 ◽  
Author(s):  
KAZUMOTO IGUCHI ◽  
KAZUHIKO AOMOTO
Keyword(s):  
Statistical Mechanics ◽  
Modular Group ◽  
Hypergeometric Functions ◽  
Chemical Potential ◽  
Quantum Statistical Mechanics ◽  
Quantum Systems ◽  
Quantum Statistical ◽  
Physical Quantities

We investigate a novel symmetry in dualities of Wu's equation: wg(1+w)1-g=eβ(ε-μ) for a degenerate g-on gas with fractional exclusion statistics of g, where β=1/k B T, ∊ the energy, and μ the chemical potential of the system. We find that the particle–hole duality between g and 1/g and the supersymmetric duality between g and 1-g form a novel quasi-modular group of order six for Wu's equation. And we show that many physical quantities in quantum systems with the fractional exclusion statistics can be represented in terms of quasi-hypergeometric functions and that the quasi-modular symmetry acts on these functions.

Equilibrium Statistical Mechanics

2019 ◽  
pp. 63-110
Author(s):  
Hans-Peter Eckle
Keyword(s):  
Statistical Mechanics ◽  
Chemical Potential ◽  
Magnetic Moments ◽  
Mean Field Theory ◽  
Mean Field ◽  
Quantum Statistical Mechanics ◽  
Quantum Gases ◽  
Einstein Condensation ◽  
Equilibrium Statistical Mechanics ◽  
Grand Canonical

Chapter 4 reviews the basic notions of equilibrium statistical mechanics and begins with its fundamental postulate and outlines the structure of the theory using the most important of the various statistical ensembles, the microcanonical, the canonical, and the grand canonical ensemble and their corresponding thermodynamic potential, the internal energy, the Helmholtz free energy, and the grand canonical potential. The notions of temperature, pressure, and chemical potential are obtained and it introduces the laws of thermodynamics, the Gibbs entropy, and the concept of the partition function. It also discusses quantum statistical mechanics using the density matrix and as applied to non-interacting Bosonic and Fermionic quantum gases, the former showing Bose–Einstein condensation. The mean-field theory of interacting magnetic moments and the transfer matrix to exactly solve the Ising model in one dimension serve as applications.

Quantum Ensembles

2019 ◽  
pp. 285-296
Author(s):  
Robert H. Swendsen
Keyword(s):  
Statistical Mechanics ◽  
Probability Distributions ◽  
Quantum Statistical Mechanics ◽  
Stationary States ◽  
Mechanical State ◽  
Many Body ◽  
Model Probability ◽  
Exact Position ◽  
Quantum Statistical ◽  
Many Body Systems

The study of quantum statistical mechanics begins with a review of the basic principles of quantum mechanics. Schrödinger’s equation is introduced and Eigenstates (or stationary states) are defined. Model probability for quantum statistics is assumed to have a uniform distribution in phases. Wave functions for many-body systems are defined. The density matrix is introduced. The Planck entropy and the microcanonical ensemble are defined. The differences between classical and quantum statistical mechanics are all based on the differing concepts of a microscopic ‘state’. While the classical microscopic state (specified by a point in phase space) determines the exact position and momentum of every particle, the quantum mechanical state determines neither; quantum states can only provide probability distributions for observable quantities.

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