Two-Dimensional Instantons with Bosonization and Physics of Adjoint QCD2
Abstract
We evaluate partition functions ZI in topologically nontrivial (instanton) gauge sectors in the bosonized version of the Schwinger model and in a gauged WZNW model corresponding to QCD2 with adjoint fermions. We show that the bosonized model is equivalent to the fermion model only if a particular form of the WZNW action with gauge-invariant integrand is chosen. For the exact correspondence, it is necessary to integrate over the ways the gauge group SU(N)/ZN is embedded into the full O(N2 - 1) group for the bosonized matter field. For even N, one should also take into account the contributions of both disconnected components in O(N2 - 1). In that case, ZI mn0 for small fermion masses where 2n0 coincides with the number of fermion zero modes in a particular instanton background. The Taylor expansion of ZI/mn0 in mass involves only even powers of m as it should. The physics of adjoint QCD2 is discussed. We argue that, for odd N, the discrete chiral symmetry Z2 Z2 present in the action is broken spontaneously down to Z2 and the fermion condensate <λ λ>0 is formed. The system undergoes a first order phase transition at Tc = 0 so that the condensate is zero at an arbitrary small temperature. It is not yet quite clear what happens for even N ≥ 4.
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