Heating up quadruply quantized vortices: Splitting patterns and dynamical transitions

Abstract

Using holographic duality, we investigate the impact of finite temperature on the instability and splitting patterns of quadruply quantized vortices, providing the first-ever analysis in this context. Through linear stability analysis, we reveal the occurrence of two consecutive dynamical transitions. At a specific low temperature, the dominant unstable mode transitions from the 2-fold rotational symmetry mode to the 3-fold one, followed by a transition from the 3-fold one to the 4-fold one at a higher temperature. As the temperature is increased, we also observe the 5 and 6-fold rotational symmetry unstable modes get excited successively. Employing the full non-linear numerical simulations, we further demonstrate that these two novel dynamical transitions, along with the temperature-induced instabilities for the 5 and 6-fold rotational symmetry modes, can be identified by examining the resulting distinct splitting patterns, which offers a promising route for the experimental verification in the cold atom gases.

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