Random Matrix Theory and Quantum Chromodynamics
Mar 18, 2016Citations per year
Abstract: (arXiv)
These notes are based on the lectures delivered at the Les Houches Summer School in July 2015. They are addressed at a mixed audience of physicists and mathematicians with some basic working knowledge of random matrix theory. The first part is devoted to the solution of the chiral Gaussian Unitary Ensemble in the presence of characteristic polynomials, using orthogonal polynomial techniques. This includes all eigenvalue density correlation functions, smallest eigenvalue distributions and their microscopic limit at the origin. These quantities are relevant for the description of the Dirac operator spectrum in Quantum Chromodynamics with three colours in four Euclidean space-time dimensions. In the second part these two theories are related based on symmetries, and the random matrix approximation is explained. In the last part recent developments are covered including the effect of finite chemical potential and finite space-time lattice spacing, and their corresponding orthogonal polynomials. We also give some open random matrix problems.Note:
- Les Houches lecture notes, Session July 2015, 37 pages, 6 figures, v2: typos corrected and grant no. added, version to appear
- matrix model: random
- density: correlation function
- space-time: dimension
- space-time: Euclidean
- space-time: lattice
- potential: chemical
- operator: spectrum
- operator: Dirac
- color: 3
- chiral
References(131)
Figures(9)
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