Spin Current Generation and Relaxation in a Quenched Spin-Orbit Coupled Bose-Einstein Condensate.

Understanding the effects of spin-orbit coupling (SOC) and many-body interactions on spin transport is important in condensed matter physics and spintronics. This topic has been intensively studied for electrons as charged fermionic carriers of spin, but barely explored for charge-neutral bosonic quasiparticles or their condensates, which have recently become promising carriers for coherent spin transport over macroscopic distances. Here, we explore the effects of synthetic SOC (induced by optical Raman coupling) and atomic interactions on the spin transport in an atomic Bose-Einstein condensate (BEC), in which the out-of-phase oscillations (spin-dipole mode, SDM, actuated by quenching the Raman coupling) of two interacting BECs of different spin states constitute an alternating spin current in a trap. We experimentally observe that SOC can significantly enhance the SDM damping, while reducing the thermalization of the BEC. Our theory, consistent with the experimental observations, reveals that the interference, immiscibility, and interaction between the two colliding spin components can be notably modified by SOC and play a crucial role in spin transport. Accompanied by the SDM damping, we also observe the generation of different BEC collective excitations such as shape oscillations. Our work may contribute to the fundamental understanding of spin transport and quenched dynamics in spin-orbit coupled systems.