Abstract
We study, by means of numerical lattice simulations, the properties of the reconfinement phase transition taking place in trace deformed $SU(3)$ Yang-Mills theory defined on $\mathbb{R}^3\times S^1$, in which center symmetry is recovered even for small compactification radii. We show, by means of a finite size scaling analysis, that the reconfinement phase transition is first-order, like the usual $SU(3)$ thermal phase transition. We then investigate two different physical phenomena, which are known to characterize the standard confinement/deconfinement phase transition, namely the condensation of thermal magnetic monopoles and the change in the localization properties of the eigenmodes of the Dirac operator. Regarding the latter, we show that the mobility edge signalling the Anderson-like transition in the Dirac spectrum vanishes as one enters the reconfined phase, as it happens in the standard confined phase. Thermal monopoles, instead, show a peculiar behavior: their density decreases going through reconfinement, at odds with the standard thermal theory; nonetheless, they condense at reconfinement, like at the usual confinement transition. The coincidence of monopole condensation and Dirac mode delocalization, even in a framework different from that of the standard confinement transition, suggests the existence of a strict link between them.
Highlights
Yang-Mills (YM) theories defined on the manifold R3 × S1, where one of the directions is compactified, undergo a phase transition as soon as the length Lc of the compactified direction becomes smaller than a critical length
By means of numerical lattice simulations, the properties of the reconfinement phase transition taking place in trace deformed SUð3Þ Yang-Mills theory defined on R3 × S1, in which center symmetry is recovered even for small compactification radii
In this paper we have studied the reconfinement phase transition of trace deformed SUð3Þ YM theory by means of lattice simulations
Summary
Yang-Mills (YM) theories defined on the manifold R3 × S1, where one of the directions is compactified, undergo a phase transition as soon as the length Lc of the compactified direction becomes smaller than a critical length. For the case of the gauge group SUð3Þ that will be studied in this paper, it consists in adding a term proportional to jTrPðx⃗ Þj2 to the YM action density The rationale behind this choice is that such a term is invariant under center symmetry and, if its coefficient is chosen with the appropriate sign, it disfavors nonvanishing values of the trace of the Polyakov loop.
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