Elliptic extensions in statistical and stochastic systems / Makoto Katori.
2023
QA343
Linked e-resources
Linked Resource
Concurrent users
Unlimited
Authorized users
Authorized users
Document Delivery Supplied
Can lend chapters, not whole ebooks
Details
Title
Elliptic extensions in statistical and stochastic systems / Makoto Katori.
ISBN
9789811995279 (electronic bk.)
9811995273 (electronic bk.)
9789811995262 (print)
9811995273 (electronic bk.)
9789811995262 (print)
Published
Singapore : Springer, 2023.
Language
English
Description
1 online resource (120 pages) : illustrations (black and white).
Item Number
10.1007/978-981-19-9527-9 doi
Call Number
QA343
Dewey Decimal Classification
515/.983
Summary
Hermite's theorem makes it known that there are three levels of mathematical frames in which a simple addition formula is valid. They are rational, q-analogue, and elliptic-analogue. Based on the addition formula and associated mathematical structures, productive studies have been carried out in the process of q-extension of the rational (classical) formulas in enumerative combinatorics, theory of special functions, representation theory, study of integrable systems, and so on. Originating from the paper by Date, Jimbo, Kuniba, Miwa, and Okado on the exactly solvable statistical mechanics models using the theta function identities (1987), the formulas obtained at the q-level are now extended to the elliptic level in many research fields in mathematics and theoretical physics. In the present monograph, the recent progress of the elliptic extensions in the study of statistical and stochastic models in equilibrium and nonequilibrium statistical mechanics and probability theory is shown. At the elliptic level, many special functions are used, including Jacobi's theta functions, Weierstrass elliptic functions, Jacobi's elliptic functions, and others. This monograph is not intended to be a handbook of mathematical formulas of these elliptic functions, however. Thus, use is made only of the theta function of a complex-valued argument and a real-valued nome, which is a simplified version of the four kinds of Jacobi's theta functions. Then, the seven systems of orthogonal theta functions, written using a polynomial of the argument multiplied by a single theta function, or pairs of such functions, can be defined. They were introduced by Rosengren and Schlosser (2006), in association with the seven irreducible reduced affine root systems. Using Rosengren and Schlosser's theta functions, non-colliding Brownian bridges on a one-dimensional torus and an interval are discussed, along with determinantal point processes on a two-dimensional torus. Their scaling limits are argued, and the infinite particle systems are derived. Such limit transitions will be regarded as the mathematical realizations of the thermodynamic or hydrodynamic limits that are central subjects of statistical mechanics.
Bibliography, etc. Note
Includes bibliographical references and index.
Access Note
Access limited to authorized users.
Source of Description
Description based on print version record.
Series
SpringerBriefs in mathematical physics ; v. 47.
Available in Other Form
Linked Resources
Record Appears in
Table of Contents
Introduction
Brownian Motion and Theta Functions
Biorthogonal Systems of Theta Functions and Macdonald Denominators
KMLGV Determinants and Noncolliding Brownian Bridges
Determinantal Point Processes Associated with Biorthogonal Systems
Doubly Periodic Determinantal Point Processes
Future Problems.
Brownian Motion and Theta Functions
Biorthogonal Systems of Theta Functions and Macdonald Denominators
KMLGV Determinants and Noncolliding Brownian Bridges
Determinantal Point Processes Associated with Biorthogonal Systems
Doubly Periodic Determinantal Point Processes
Future Problems.