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Dynamical Phase Transition from Nonequilibrium Dynamics of Dark Solitons

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 Added by Minyong Guo
 Publication date 2018
  fields Physics
and research's language is English




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By holographic duality, we identify a novel dynamical phase transition which results from the temperature dependence of non-equilibrium dynamics of dark solitons in a superfluid.For a non-equilibrium superfluid system with an initial density of dark solitons, there exists a critical temperature $T_d$,above which the system relaxes to equilibrium by producing sound waves, while below which it goes through an intermediate phase with a finite density of vortex-antivortex pairs. In particular, as $T_d$ is approached from below, the density of vortex pairs scales as $(T_d - T)^gamma$ with the critical exponent $gamma = 1/2$.



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118 - D. M. Kennes , D. Schuricht , 2018
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