Quantum enhancement of spin drag in a Bose gas
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Publication date
2015-11-09
Authors
Koller, S.B.
Groot, A.
Bons, P. C.
Duine, R. A.
Stoof, Henk
Van der Straten, P.
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Article
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Abstract
In spintronics the active control and manipulation of spin currents is studied in solid-state systems. Opposed to charge currents, spin currents are strongly damped due to collisions between different spin carriers in addition to relaxation due to impurities and lattice vibrations. The phenomenon of relaxation of spin currents is called spin drag. Here we study spin drag in ultra-cold bosonic atoms deep in the hydrodynamic regime and show that spin drag is the dominant damping mechanism for spin currents in this system. By increasing the phase space density we find that spin drag is enhanced in the quantum regime by more than a factor of two due to Bose stimulation, which is in agreement with recent theoretical predictions and, surprisingly, already occurs considerably above the phase transition.
Keywords
ultracold gases, hydrodynamics, spin transport, FERMI GAS, SPINTRONICS, FUTURE
Citation
Koller, S B, Groot, A, Bons, P C, Duine, R A, Stoof, H T C & van der Straten, P 2015, 'Quantum enhancement of spin drag in a Bose gas', New Journal of Physics, vol. 17, 113026. https://doi.org/10.1088/1367-2630/17/11/113026