Abstract
We explore the influence of contact interactions on a synthetically spin–orbit coupled system of two ultracold trapped atoms. Even though the system we consider is bosonic, we show that a regime exists in which the competition between the contact and spin–orbit interactions results in the emergence of a ground state that contains a significant contribution from the anti-symmetric spin state. This ground state is unique to few-particle systems and does not exist in the mean-field regime. The transition to this state is signalled by an inversion in the average momentum from being dominated by centre-of-mass momentum to relative momentum and also affects the global entanglement shared between the real- and pseudo-spin spaces. Indeed, competition between the interactions can also result in avoided crossings in the ground state which further enhances these correlations. However, we find that correlations shared between the pseudo-spin states are strongly depressed due to the spin–orbit coupling and therefore the system does not contain spin–spin entanglement.
Highlights
Spin–orbit coupling (SOC) is an effect that was initially discussed in systems of charged particles
Bose–Einstein condensates (BECs) coupled by Raman lasers can be used to generate synthetic SOC, using a pseudo-spin realised by two internal states of the atoms and selective momentum transfer
We find that the interplay between the contact interactions and the SOC leads to lifting of degeneracies in the energy spectrum, which in certain parameter regimes results in the appearance of a unique ground state that is not revealed within a mean-field treatment
Summary
Ayaka Usui , Thomás Fogarty , Steve Campbell , Simon A Gardiner and Thomas Busch1 Original content from this Abstract work may be used under We explore the influence of contact interactions on a synthetically spin–orbit coupled system of two the terms of the Creative Commons Attribution 3.0 ultracold trapped atoms. Any further distribution of this work must maintain a ground state that contains a significant contribution from the anti-symmetric spin state. This ground attribution to the author(s) and the title of state is unique to few-particle systems and does not exist in the mean-field regime. We find that correlations shared between the pseudo-spin states are strongly depressed due to the spin–orbit coupling and the system does not contain spin–spin entanglement
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