Eigenvalue Dynamics and the Matrix Chain
Abstract
We introduce a general method for transforming the equations of motion following from a Das-Jevicki-Sakita Hamiltonian, with boundary conditions, into a boundary value problem in one-dimensional quantum mechanics. For the particular case of a one-dimensional chain of interacting NxN Hermitean matrices, the corresponding large N boundary value problem is mapped into a linear Fredholm equation with Hilbert-Schmidt type kernel. The equivalence of this kernel, in special cases, to a second order differential operator allows us recover all previously known explicit solutions for the matrix eigenvalues. In the general case, the distribution of eigenvalues is formally derived through a series of saddle-point approximations. The critical behaviour of the system, including a previously observed Kosterlitz-Thouless transition, is interpreted in terms of the stationary points. In particular we show that a previously conjectured infinite series of sub-leading critical points are due to expansion about unstable stationary points and consequently not realized.
Cite
@article{arxiv.hep-th/9902089,
title = {Eigenvalue Dynamics and the Matrix Chain},
author = {L. D. Paniak},
journal= {arXiv preprint arXiv:hep-th/9902089},
year = {2009}
}
Comments
20 pages, LaTeX. Typos and conflicts in notation resolved