Bubble dynamics and vortex formation in holographic first-order superfluid phase transitions

TL;DR

This paper studies bubble dynamics, vortex formation, and critical behavior in a holographic superfluid undergoing a first-order phase transition, revealing universal scaling laws and complex defect formation mechanisms.

Contribution

It introduces a detailed analysis of vortex formation and critical phenomena in holographic superfluids, highlighting deviations from classical rules and new defect dynamics.

Findings

Universal critical behavior near nucleation threshold

Vortex-antivortex pairs form in three-bubble collisions

Lifetime of vortex pairs scales logarithmically with collision parameters

Abstract

We investigate bubble dynamics in a holographic superfluid undergoing a first-order phase transition with spontaneous $U(1)$ symmetry breaking. Near the nucleation threshold, the system exhibits universal critical behavior governed by a single unstable mode, leading to logarithmic scaling of the time spent near the critical solution. The terminal bubble wall velocity increases with charge density but remains small due to strong dissipation. In multi-bubble collisions, vortex formation depends sensitively on the initial phases and deviates significantly from the geodesic rule. Notably, we identify a regime where three-bubble collisions produce a vortex-antivortex pair that subsequently annihilates, a phenomenon not predicted by the geodesic rule. The lifetime of this pair scales logarithmically with the distance to the critical collision radius. Our results underscore the crucial role of non-equilibrium dynamics in strongly coupled superfluids and provide new insights into topological defect formation during first-order phase transitions.