The non-minimally coupled gravitating vortex: phase transition at critical coupling c in AdS3

Abstract

We consider the Nielsen-Olesen vortex non-minimally coupled to Einstein gravity with cosmological constant . A non-minimal coupling term \,R\,|φ|2 is natural to add to the vortex as it preserves gauge-invariance (here R is the Ricci scalar and a dimensionless coupling constant). This term plays a dual role: it contributes to the potential of the scalar field and to the Einstein-Hilbert term for gravity. As a consequence, the vacuum expectation value (VEV) of the scalar field and the cosmological constant in the AdS3 background depend on . This leads to a novel feature: there is a critical coupling c where the VEV is zero for c but becomes non-zero when crosses below c and the gauge symmetry is spontaneously broken. Moreover, we show that the VEV near the critical coupling has a power law behaviour proportional to |-c|1/2. Therefore c can be viewed as the analog of the critical temperature Tc in Ginzburg-Landau (GL) mean-field theory where a second-order phase transition occurs below Tc and the order parameter has a similar power law behaviour |T-Tc|1/2 near Tc. The critical coupling exists only in an AdS3 background; it does not exist in asymptotically flat spacetime (topologically a cone) where the VEV remains at a fixed non-zero value independent of . However, the deficit angle of the asymptotic conical spacetime depends on and is no longer determined solely by the mass; remarkably, a higher mass does not necessarily yield a higher deficit angle. The equations of motion are more complicated with the non-minimal coupling term present. However, via a convenient substitution one can reduce the number of equations and solve them numerically to obtain exact vortex solutions.

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