Rui Gao scite author profile

Rui Gao

5Publications

3Citation Statements Received

64Citation Statements Given

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203

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Northwest Normal University

Publications

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Interaction of chiral solitons in a Bose-Einstein Condensate under density-dependent gauge potential

Gao

Qiao

et al. 2023

EPL

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The collision between two chiral solitons in a Bose−Einstein Condensate (BEC) under density−dependent gauge potential is studied. By means of Poincaree−Lighthill−Kuo (PLK) perturbation method, the different kinds of colliding chiral soliton pairs self−consistently excited upon the background of the system are obtained analytically. The coupling of the current nonlinearity induced by the gauge potential and mean−field atomic interaction results in rich collision dynamics of chiral soliton pairs. When the atomic interaction is repulsive, head−on collisions of dark−dark and dark−bright solitons are observed. However, when the atomic interaction is attractive, unidirectional chiral dark soliton pairs are excited, and overtaking collision between two chiral dark solitons takes place. The phase shifts following the collision of soliton pairs are derived analytically and confirmed numerically. Interestingly, due to the contribution of the density−dependent gauge potential, the phase shifts of the two interacting chiral solitons are different from each other. This is distinct from the case without the density−dependent gauge potential, where the phase shifts of the two colliding ordinary solitons are the same. Thus, phase shifts of interacting chiral soliton pairs can be used to identify the chiral properties of solitons in BEC under density−dependent gauge potential. Furthermore, both elastic and inelastic collisions of chiral solitons in the system are presented numerically. The phase diagram for occurrence of elastic and inelastic collisions of chiral soliton is obtained, which strongly depends on the strength of density−dependent gauge potential.

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Chiral matter-wave soliton in a Bose-Einstein condensate under density-dependent gauge potential

Gao

Qiao²,

Ma³

et al. 2022

Physics Letters A

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Tunneling dynamics of tunable spin-orbit coupled Bose-Einstein condensates

Ma¹,

Qiao²,

Gao³

et al. 2022

Acta Phys. Sin.

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We theoretically study the band structure, tunneling dynamics, and tunneling probability of tunable spin-orbit-coupled Bose-Einstein condensates under the periodic driving of Raman coupling. The time-independent Floquet Hamiltonian is obtained in the high-frequency approximation. It is found that the periodic driving can effectively tune spin-orbit coupling and nonlinear interaction. The system is mapped to a standard nonlinear two-level model, and the critical condition for the appearance of the loop in energy band structure and the width of the loop are obtained analytically. When the interspecies atomic interaction is equal to the intraspecies atomic interaction, there is no loop. However, when the intraspecies atomic interaction is smaller (larger) than the interspecies atomic interaction, the loop appears in the lower (upper) energy band. In this case, both spin-orbit coupling and Raman coupling will suppress the appearance of loop. In particular, the critical condition for the appearance of loop structure can be controlled by adjusting external driving. We also study the tunneling dynamics of Bose-Einstein condensate with tunable spin-orbit coupling. More importantly, by tuning the periodic driving, the tunneling dynamics of the system and the location of nonlinear Landau-Zener tunneling can be controlled. We also find that the spin components of the system can be reversed. Finally, the Landau-Zener tunneling probability of the system is calculated. The research shows that the periodic driving can effectively change the tunneling probability of the system.

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Modulational Instability of Trapped Two-Component Bose–Einstein Condensates*

Zhou¹,

Li²,

Gao³

et al. 2019

Chinese Phys. Lett.

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The modulational instability of two-component Bose–Einstein condensates (BECs) under an external parabolic potential is discussed. Based on the trapped two-component Gross–Pitaevskill equations, a time-dependent dispersion relation is obtained analytically by means of the modified lens-type transformation and linear stability analysis. It is shown that a modulational unstable time scale exists for trapped two-component BECs. The modulational properties—which are determined by the wave number, external trapping parameter, intra- and inter-species atomic interactions—are modified significantly. The analytical results are confirmed by direct numerical simulation. Our results provide a criterion for judging the occurrence of instability of the trapped two-component BECs in experiment.

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Tunneling dynamics of spin-orbit coupled BECs in a one-dimensional accelerating optical lattice

Qiao

Gao

et al. 2022

Mod. Phys. Lett. B

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We theoretically investigate the energy band structure, nonlinear Landau–Zener tunneling dynamics and tunneling probability of spin-orbit coupled Bose–Einstein condensates in a one-dimensional accelerating optical lattice by using mean-field and two-mode approximation. The critical condition for the appearance of the loop structure is obtained numerically in parameter planes. When the intraspecies atomic interaction is less than the interspecies atomic interaction, the loop only appears in the lower band. In this case, Raman coupling inhibits the appearance of loop, while spin-orbit coupling (SOC) promotes the appearance of loop. If the intraspecies atomic interaction is larger than interspecies atomic interaction, the loop can appear in either the upper band or the lower band. In this case, Raman coupling promotes the loop appearing in the lower band, while SOC suppresses the loop appearing in upper band. Interestingly, when the interspecies atomic interaction is equal to the intraspecies atomic interaction, there is a critical atomic intercation value determined by the optical lattice depth, only when the intraspecies atomic interaction is greater than the critical value, the loop will occur only in lower band. Especially, the emergence of the loop structure destroys the Bloch oscillation of the system and results in the nonlinear Landau–Zener tunneling of the system. Furthermore, the Landau–Zener tunneling probability of the system is calculated, and it is found that the nonlinear Landau–Zener dynamics and the tunneling probability can be manipulated by SOC and Raman coupling.

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Rui Gao

Interaction of chiral solitons in a Bose-Einstein Condensate under density-dependent gauge potential

Chiral matter-wave soliton in a Bose-Einstein condensate under density-dependent gauge potential

Tunneling dynamics of tunable spin-orbit coupled Bose-Einstein condensates

Modulational Instability of Trapped Two-Component Bose–Einstein Condensates*

Tunneling dynamics of spin-orbit coupled BECs in a one-dimensional accelerating optical lattice

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