Counting Strings and Phase Transitions in 2D QCD

Abstract

Several string theories related to QCD in two dimensions are studied. For each of these theories the large N free energy on a (target) sphere of area A is calculated. By considering theories with different subsets of the geometrical structures involved in the full QCD2 string theory, the different contributions of these structures to the string free energy are calculated using both analytic and numerical methods. The equivalence between the leading terms in the SU(N) and U(N) free energies is simply demonstrated from the string formulation. It is shown that when -points are removed from the theory, the free energy is convergent for small and large values of A but divergent in an intermediate range. Numerical results indicate that the free energy for the full QCD2 string fails to converge at the Douglas-Kazakov phase transition point. Similar results for a single chiral sector of the theory, such as has recently been studied by Cordes, Moore, and Ramgoolam, indicate that there are three distinct phases in that theory. These results indicate that from the point of view of the strong coupling phase, the phase transition in the full QCD2 string arises from the entropy of branch-point singularities.

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