Emergent gauge field and the Lifshitz transition of spin-orbit coupled bosons in one dimension

Abstract: In the presence of strong spin-independent interactions and spin-orbit coupling, we show that the spinor Bose liquid confined to one spatial dimension undergoes an interaction- or density-tuned quantum phase transition similar to one theoretically proposed for itinerant magnetic solid-state systems. The order parameter describes broken Z 2 inversion symmetry, with the ordered phase accompanied by non-vanishing momentum which is generated by fluctuations of an emergent dynamical gauge fie… Show more

“…In the strongly correlated regime [42,43], the SOC spin-1 Bose-Hubbard model at the odd integer filled Mott lobes can be mapped to an insulating quantum spin-1 magnet in a helical magnetic field which tunes a quantum phase transition [44,45]. However, on the other hand, the strongly correlated superfluid regime of dilute bosons in 1D in the presence of a SOC has not yet received much attention, despite the potentially rich magnetic phenomena due to the spin-1 nature of the problem, which extends beyond the spin-1/2 case [32,46].…”

Strongly interacting spin-orbit coupled Bose-Einstein condensates in one dimension

“…In the strongly correlated regime [42,43], the SOC spin-1 Bose-Hubbard model at the odd integer filled Mott lobes can be mapped to an insulating quantum spin-1 magnet in a helical magnetic field which tunes a quantum phase transition [44,45]. However, on the other hand, the strongly correlated superfluid regime of dilute bosons in 1D in the presence of a SOC has not yet received much attention, despite the potentially rich magnetic phenomena due to the spin-1 nature of the problem, which extends beyond the spin-1/2 case [32,46].…”

Strongly interacting spin-orbit coupled Bose-Einstein condensates in one dimension

Constrained Motions and Slow Dynamics in One-Dimensional Bosons with Double-Well Dispersion