10.6084/m9.figshare.1012037.v1
Wei Zheng
Wei
Zheng
Zeng-Qiang Yu
Zeng-Qiang
Yu
Xiaoling Cui
Xiaoling
Cui
Hui Zhai
Hui
Zhai
<em>T</em><sub>c</sub> (a) and its relative shift from non-interacting Bose gases Δ<em>T</em><sub>c</sub>/<em>T</em><sub>c</sub> (b) of a uniform system as a function of Ω/<em>E</em><sub>r</sub> for various interaction strengths
IOP Publishing
2013
Galilean invariance
Bose gases
uniform system
transition temperature
atom experiments
Bose gas
tc
condensate depletion
BEC transition temperature
interaction strengths
Atomic Physics
Molecular Physics
2013-06-24 00:00:00
Figure
https://iop.figshare.com/articles/figure/_em_T_em_sub_c_sub_a_and_its_relative_shift_from_non_interacting_Bose_gases_em_T_em_sub_c_sub_em_T_e/1012037
<p><strong>Figure 8.</strong> <em>T</em><sub>c</sub> (a) and its relative shift from non-interacting Bose gases Δ<em>T</em><sub>c</sub>/<em>T</em><sub>c</sub> (b) of a uniform system as a function of Ω/<em>E</em><sub>r</sub> for various interaction strengths. Here n/k^3_{\mathrm{r}}=5.</p> <p><strong>Abstract</strong></p> <p>In this paper we investigate the properties of Bose gases with Raman-induced spin–orbit (SO) coupling. It is found that the SO coupling can greatly modify the single-particle density of state, and thus leads to the non-monotonic behaviour of the condensate depletion, the Lee–Huang–Yang correction of ground-state energy and the transition temperature of a non-interacting Bose–Einstein condensate (BEC). The presence of the SO coupling also breaks the Galilean invariance, and this gives two different critical velocities, corresponding to the movement of the condensate and the impurity respectively. Finally, we show that with the SO coupling, the interactions modify the BEC transition temperature even at the Hartree–Fock level, in contrast to the ordinary Bose gas without the SO coupling. All results presented here can be directly verified in the current cold atom experiments using the Raman laser-induced gauge field.</p>