Related papers: Spin-tensor Meissner currents of ultracold bosonic gas in an optical lattice

Spin-tensor Meissner currents of ultracold bosonic gas in an optical lattice

URL: http://arxiv.org/abs/2301.05054v2
Date: Thu, 8 Jun 2023 04:52:28 GMT
Title: Spin-tensor Meissner currents of ultracold bosonic gas in an optical lattice
Authors: Xiaofan Zhou, Suotang Jia, and Xi-Wang Luo
Abstract summary: We investigate the Meissner currents of interacting bosons subjected to a staggered artificial gauge field in a three-leg ribbon geometry. The currents are uniform along each leg in the Meissner phase and form vortex-antivortex pairs in the vortex phase. Our work provides useful guidance to ongoing experimental research on synthetic flux ribbons.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: We investigate the Meissner currents of interacting bosons subjected to a staggered artificial gauge field in a three-leg ribbon geometry, realized by spin-tensor--momentum coupled spin-1 atoms in a 1D optical lattice. By calculating the current distributions using the state-of-the-art density-matrix renormalization-group method, we find a rich phase diagram containing interesting Meissner and vortex phases, where the currents are mirror symmetric with respect to the {\color{red}middle leg} (i.e., they flow in the same direction on the two boundary legs opposite to that on the middle leg), leading to the spin-tensor type Meissner currents, which is very different from previously observed chiral edge currents under uniform gauge field. The currents are uniform along each leg in the Meissner phase and form vortex-antivortex pairs in the vortex phase. Besides, the system also support a polarized phase that spontaneously breaks the mirror symmetry, whose ground states are degenerate with currents either uniform or forming vortex-antivortex pairs. We also discuss the experimental schemes for probing these phases. Our work provides useful guidance to ongoing experimental research on synthetic flux ribbons and paves the way for exploring novel many-body phenomena therein.

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