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Stable two-dimensional soliton complexes in Bose–Einstein condensates with helicoidal spin–orbit coupling

Yaroslav V. Kartashov, E. Ya. Sherman, Boris A. Malomed, V. V. Konotop

2020New Journal of Physics25 citationsDOIOpen Access PDF

Abstract

Abstract We show that attractive two-dimensional (2D) spinor Bose–Einstein condensates with helicoidal spatially periodic spin–orbit coupling (SOC) support a rich variety of stable fundamental solitons and bound soliton complexes. Such states exist with chemical potentials belonging to the semi-infinite gap in the band spectrum created by the periodically modulated SOC. All these states exist above a certain threshold value of the norm. The chemical potential of fundamental solitons attains the bottom of the lowest band, whose locus is a ring in the space of Bloch momenta, and the radius of the non-monotonous function of the SOC strength. The chemical potential of soliton complexes does not attain the band edge. The complexes are bound states of several out-of-phase fundamental solitons whose centers are placed at local maxima of the SOC-modulation phase. In this sense, the impact of the helicoidal SOC landscape on the solitons is similar to that of a periodic 2D potential. In particular, it can compensate repulsive forces between out-of-phase solitons, making their bound states stable. Extended stability domains are found for complexes built of two and four solitons (dipoles and quadrupoles, respectively). They are typically stable below a critical value of the chemical potential.

Topics & Concepts

PhysicsSpinorSolitonBound stateQuantum mechanicsBose–Einstein condensateDipoleParameter spaceCondensed matter physicsNonlinear systemMathematicsStatisticsCold Atom Physics and Bose-Einstein CondensatesPhysics of Superconductivity and MagnetismStrong Light-Matter Interactions
Stable two-dimensional soliton complexes in Bose–Einstein condensates with helicoidal spin–orbit coupling | Litcius