Quantum Liouville theory in the background field formalism I. Compact Riemann surfaces
Abstract
Using Polyakov's functional integral approach with the Liouville action functional defined in ZT2 and LTT, we formulate quantum Liouville theory on a compact Riemann surface X of genus g > 1. For the partition function <X> and for the correlation functions with the stress-energy tensor components <Πi=1nT(zi)Πk=1lT(k)X>, we describe Feynman rules in the background field formalism by expanding corresponding functional integrals around a classical solution - the hyperbolic metric on X. Extending analysis in LT1,LT2,LT-Varenna,LT3, we define the regularization scheme for any choice of global coordinate on X, and for Schottky and quasi-Fuchsian global coordinates we rigorously prove that one- and two-point correlation functions satisfy conformal Ward identities in all orders of the perturbation theory. Obtained results are interpreted in terms of complex geometry of the projective line bundle c=λHc/2 over the moduli space Mg, where c is the central charge and λH is the Hodge line bundle, and provide Friedan-Shenker FS complex geometry approach to CFT with the first non-trivial example besides rational models.
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