10.6084/m9.figshare.1012190.v1
Shu-Wei Song
Yi-Cai Zhang
Lin Wen
Hanquan Wang
The SO-coupling-energy function <em>H<sub>s</sub></em> of δ<sub>1</sub> and δ<sub>−1</sub> with η = 0.0096 and κ = 2.0
2013
IOP Publishing
equilibrium position
moment
displacement decreases
atom densities
quantum numbers
calculations show
condensate
strength
square vortex lattice phase
Ground State
z direction
2013-06-27 00:00:00
article
https://iop.figshare.com/articles/_The_SO_coupling_energy_function_em_H_sub_s_sub_em_of_sub_1_sub_and_sub_1_sub_with_0_0096_and_2_0/1012190
<p><strong>Figure 2.</strong> The SO-coupling-energy function <em>H<sub>s</sub></em> of δ<sub>1</sub> and δ<sub>−1</sub> with η = 0.0096 and κ = 2.0. The light-red balls at points δ<sub>1</sub> = δ<sub>−1</sub> = 0 feel forces pointing to the equilibrium position. The units of <em>H<sub>s</sub></em> and δ<sub>±1</sub> are ω and a_{\perp }=\sqrt{\hbar /M\omega }, respectively.</p> <p><strong>Abstract</strong></p> <p>We analytically and numerically investigate the ground state of spin–orbit coupled spin-1 Bose–Einstein condensates in an external parabolic potential. When the spin–orbit coupling is introduced, spatial displacement exists between the atom densities of components with different magnetic quantum numbers. The analytical calculations show this displacement reaches a maximum when the spin–orbit coupling strength is comparable with that of the trapping potential. As the spin–orbit coupling strength gets larger and larger, the spatial displacement decreases at a rate inversely proportional to the spin–orbit coupling strength. Correspondingly, periphery half-skyrmion textures arise; this displacement can be reflected by the non-uniform magnetic moment in the <em>z</em> direction. With the manipulation of the external trap, the local magnitude of the non-uniform magnetic moment can be increased evidently. This kind of increase of the local magnetic moment is also observed in the square vortex lattice phase of the condensate.</p>