Holographic Thermal Relaxation in Superfluid Turbulence

Yiqiang Du; Chao Niu; Yu Tian; Hongbao Zhang

doi:10.1007/JHEP12(2015)018

Holographic Thermal Relaxation in Superfluid Turbulence

Yiqiang Du, Chao Niu, Yu Tian, Hongbao Zhang

Physics

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32 Citations (Scopus)

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Abstract

Holographic duality provides a first-principles approach to investigate real time processes in quantum many-body systems, in particular at finite temperature and far-from-equilibrium. We use this approach to study the dynamical evolution of vortex number in a two-dimensional (2D) turbulent superfluid through numerically solving its gravity dual. We find that the temporal evolution of the vortex number can be well fit statistically by two-body decay due to the vortex pair annihilation featured relaxation process, thus confirm the previous suspicion based on the experimental data for turbulent superfluid in highly oblate Bose-Einstein condensates. Furthermore, the decay rate near the critical temperature is in good agreement with the recently developed effective theory of 2D superfluid turbulence.

Original language	English
Article number	18
Number of pages	11
Journal	The Journal of high energy physics
Volume	2015
Issue number	12
DOIs	https://doi.org/10.1007/JHEP12(2015)018
Publication status	Published - 2 Dec 2015

Bibliographical note

14 pages, version to appear in JHEP. Movies available at http://people.ucas.ac.cn/~ytian?language=en#171556

Keywords

hep-th
cond-mat.quant-gas
gr-qc

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10.1007/JHEP12(2015)018

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SRP8: Strategic Research Programme: High-Energy Physics at the VUB
D'Hondt, J. (Administrative Promotor), Van Eijndhoven, N. (Co-Promotor), Craps, B. (Co-Promotor) & Buitink, S. (Co-Promotor)
1/11/12 → 31/10/24
Project: Fundamental

Cite this

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title = "Holographic Thermal Relaxation in Superfluid Turbulence",

abstract = "Holographic duality provides a first-principles approach to investigate real time processes in quantum many-body systems, in particular at finite temperature and far-from-equilibrium. We use this approach to study the dynamical evolution of vortex number in a two-dimensional (2D) turbulent superfluid through numerically solving its gravity dual. We find that the temporal evolution of the vortex number can be well fit statistically by two-body decay due to the vortex pair annihilation featured relaxation process, thus confirm the previous suspicion based on the experimental data for turbulent superfluid in highly oblate Bose-Einstein condensates. Furthermore, the decay rate near the critical temperature is in good agreement with the recently developed effective theory of 2D superfluid turbulence.",

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AU - Du, Yiqiang

AU - Niu, Chao

AU - Tian, Yu

AU - Zhang, Hongbao

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PY - 2015/12/2

Y1 - 2015/12/2

N2 - Holographic duality provides a first-principles approach to investigate real time processes in quantum many-body systems, in particular at finite temperature and far-from-equilibrium. We use this approach to study the dynamical evolution of vortex number in a two-dimensional (2D) turbulent superfluid through numerically solving its gravity dual. We find that the temporal evolution of the vortex number can be well fit statistically by two-body decay due to the vortex pair annihilation featured relaxation process, thus confirm the previous suspicion based on the experimental data for turbulent superfluid in highly oblate Bose-Einstein condensates. Furthermore, the decay rate near the critical temperature is in good agreement with the recently developed effective theory of 2D superfluid turbulence.

AB - Holographic duality provides a first-principles approach to investigate real time processes in quantum many-body systems, in particular at finite temperature and far-from-equilibrium. We use this approach to study the dynamical evolution of vortex number in a two-dimensional (2D) turbulent superfluid through numerically solving its gravity dual. We find that the temporal evolution of the vortex number can be well fit statistically by two-body decay due to the vortex pair annihilation featured relaxation process, thus confirm the previous suspicion based on the experimental data for turbulent superfluid in highly oblate Bose-Einstein condensates. Furthermore, the decay rate near the critical temperature is in good agreement with the recently developed effective theory of 2D superfluid turbulence.

KW - hep-th

KW - cond-mat.quant-gas

KW - gr-qc

U2 - 10.1007/JHEP12(2015)018

DO - 10.1007/JHEP12(2015)018

M3 - Article

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VL - 2015

JO - The Journal of high energy physics

JF - The Journal of high energy physics

IS - 12

M1 - 18

ER -

Holographic Thermal Relaxation in Superfluid Turbulence

Abstract

Bibliographical note

Keywords

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Projects

SRP8: Strategic Research Programme: High-Energy Physics at the VUB

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