Related papers: Anomalous Trajectory Drift and Geometric Phases of Cyclic Spinor Solitons Induced by Virtual Magnetic Monopoles

Anomalous Trajectory Drift and Geometric Phases of Cyclic Spinor Solitons Induced by Virtual Magnetic Monopoles

URL: http://arxiv.org/abs/2509.13800v1
Date: Wed, 17 Sep 2025 08:15:41 GMT
Title: Anomalous Trajectory Drift and Geometric Phases of Cyclic Spinor Solitons Induced by Virtual Magnetic Monopoles
Authors: Ruo-Yun Wu, Ning Mao, Xiao-Lin Li, Jie Liu, Li-Chen Zhao,
Abstract summary: We investigate the dynamics of a two-component Bose-Einstein condensate with spin-orbit coupling numerically and analytically.<n>We observe that the system exhibits cyclic soliton motion; however, the trajectory of the soliton center shows a distinct drift.<n>The underlying mechanism of this anomalous drift is revealed: the moving soliton experiences a Lorentz force induced by a virtual magnetic monopole field in momentum space.
Score: 8.63790768401275
License: http://creativecommons.org/licenses/by/4.0/
Abstract: We investigate the dynamics of a two-component Bose-Einstein condensate with spin-orbit coupling numerically and analytically. Under the drive of a weak segmented rotational external field, we observe that the system exhibits cyclic soliton motion; however, in contrast to the predictions of quasi-particle theory, the trajectory of the soliton center shows a distinct drift. The underlying mechanism of this anomalous drift is revealed: the moving soliton experiences a Lorentz force induced by a virtual magnetic monopole field in momentum space. We further calculate the phase evolution of the soliton during this cyclic motion and find that its geometric component comprises both an adiabatic Berry phase and a nonadiabatic Aharonov-Anandan phase. Notably, the Berry phase can be expressed in terms of the magnetic flux of the aforementioned virtual monopole field. Our findings hold implications for geometric phase theory and experiments on two-component Bose-Einstein condensates, and may establish a novel link between quantum geometry and soliton dynamics.

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