Confining Strings and Glueballs in ZN Gauge Theories
Abstract
Effective string theory has shown its universal power in the prediction of the spectrum of low-lying excited states of confining strings. Here we study confining flux tubes in ZN gauge theories. For the N=2 theory, which corresponds to the 3d Ising gauge model, we compute the spectrum of low-lying excitations of confining strings and show that it agrees with the universal Nambu--Goto predictions except for an additional massive scalar resonance. This resonance, however, turns out to be a bulk glueball mixing with the flux tube excitations rather than a genuine string worldsheet state. In general ZN gauge theories (dual to clock spin models), we observe a continuous phase transition for N ≥ 4, while for N > 5 it is governed by the O(2) universality class. The critical behavior of the string tension and mass gap is verified to be described by a dangerously irrelevant operator. At large N the glueball spectrum is expected to approach the spectrum of U(1) gauge theory, which is confirmed by our lattice data.
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