Wednesday, August 15, 2012

1208.2923 (Jonas Larson et al.)

Chaos-driven dynamics in spin-orbit coupled atomic gases    [PDF]

Jonas Larson, Brandon Anderson, Alexander Altland
The dynamics, appearing after a quantum quench, of a trapped, spin-orbit coupled, dilute atomic gas is studied. The characteristics of the evolution is greatly influenced by the symmetries of the system, and we especially compare evolution for an isotropic Rashba coupling and for an anisotropic spin-orbit coupling. As we break the rotational symmetry by making the spin-orbit coupling anisotropic, the underlying classical model is chaotic and the quantum dynamics is affected accordingly. Within experimentally relevant time-scales and parameters, the system thermalizes in a quantum sense. The corresponding equilibration time is found to agree with the Ehrenfest time, i.e. we numerically verify a ~log(1/h) scaling. Upon thermalization, we find the equilibrated distributions show examples of quantum scars distinguished by accumulation of atomic density for certain energies. At shorter time-scales we discuss non-adiabatic effects deriving from the spin-orbit coupled induced Dirac point. In the vicinity of the Dirac point, spin fluctuations are large and, even at short times, a semi-classical analysis fails.
View original: http://arxiv.org/abs/1208.2923

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