Spielman, I.
, Tao, J.
, Mercado Gutierrez, E.
and Zhao, M.
(2026),
Imaginary gauge potentials in a non-Hermitian spin-orbit coupled quantum gas, Physical Review Letters, [online], https://tsapps.nist.gov/publication/get_pdf.cfm?pub_id=959748 (Accessed May 9, 2026)
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Imaginary gauge potentials in a non-Hermitian spin-orbit coupled quantum gas
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Author(s)
, Junheng Tao, , Mingshu Zhao
Abstract
In 1996, Hatano and Nelson proposed a non-Hermitian lattice model containing an imaginary Peierls phase [Phys.Rev.Lett.\bf 77}570--573 (1996)], which subsequent analyses revealed to be an instance of a new class of topological systems. Here, we experimentally realize a continuum analog to this model containing an imaginary gauge potential using a homogeneous spin-orbit coupled Bose-Einstein condensate (BEC). Non-Hermiticity is introduced by adding tunable spin-dependent loss via microwave coupling to a subspace with spontaneous emission. We demonstrate that the resulting Heisenberg equations of motion for position and momentum depend explicitly on the system's phase-space distribution. First, we observe collective nonreciprocal transport in real space, with a ''self-acceleration'' that decreases with the BEC's spatial extent, consistent with non-Hermitian Gross-Pitaevskii simulations. We then examine localized edge states: the relatively strong interactions in our BEC suppress the formation of topological edge states, yielding instead highly excited states localized by an interplay between self-acceleration and wavefunction spreading. Finally, we confirm that our non-Hermitian description remains valid at all times by comparing to a multi-level master-equation treatment.Citation
Physical Review Letters
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Created March 17, 2026, Updated May 8, 2026