HET Seminar | Daniel Kapec, Member, School of Natural Sciences, IAS |"Comments on the Quantum Field Theory of the Coulomb Gas Formalism" | via Zoom

Fri, Feb 19, 2021, 1:45 pm
Location: 
via Zoom
Speaker(s): 

To connect to the HET Seminar via Zoom, please click the following link:
https://theias.zoom.us/j/96660745132?pwd=Y3FPUWVDZlNwUEdINkxjSnNhK0dpZz09

Abstract: I will revisit the quantum field theory of the Coulomb gas formalism, clarifying several important points along the way. The first key ingredient involves a peculiarity of the timelike linear dilaton: although the background charge Q breaks the scalar field’s continuous shift symmetry, the exponential of the action is still invariant under a discrete shift since Q is imaginary. Gauging this symmetry makes the linear dilaton compact and introduces winding modes into the spectrum. One of these winding operators corresponds to a BRST current first introduced by Felder, and the BRST cohomology singles out the minimal model operators within the linear dilaton theory. The model at radius R=pp′R=\sqrt{pp \prime}  has two marginal operators corresponding to the Dotsenko-Fateev screening charges. Deforming by them, one obtains a model that might be called a “BRST quotiented compact timelike Liouville theory” with many interesting properties which I will describe. Applying conformal perturbation theory to the exponential interactions reproduces the Coulomb gas calculations of minimal model correlators and allows for a kinematic derivation of the fusion rules. In contrast to spacelike Liouville, these resonance correlators are finite because the zero mode is compact.