Negative moment of inertia of large-Nc gluons on a ring

Abstract

We study SU(Nc) Yang-Mills theory in 1+1 dimensions at finite temperature on a spatial ring that rotates uniformly in a plane. We show that the effect of rotation results only in a simple kinematic enhancement of the gauge coupling g, which becomes rescaled by a Lorentz factor corresponding to the tangential rotational velocity of the ring. Using well-established analytic results in Yang-Mills theory in the 't Hooft limit of an infinite number of colors, we demonstrate that the moment of inertia of the large-Nc gluon plasma on the ring is negative. This counterintuitive conclusion is, however, in agreement with recent first-principle numerical simulations of hot 3+1 dimensional SU(3) Yang-Mills theory that also reported a negative moment of inertia for gluon plasma in an experimentally relevant window of temperatures above the deconfinement transition. Furthermore, we argue that our picture provides a qualitative explanation for three other intriguing features observed in lattice simulations of vortical QCD: the emergence of a spatially inhomogeneous mixed phase, the inconsistency of its spatial structure with a standard picture dictated by the Tolman-Ehrenfest law, and the enhancement of the critical deconfining temperature by rotation.