Long-range spin transport on the surface of topological Dirac semimetal

TL;DR

This paper proposes a theoretical model for long-range, low-dissipation spin transport on the surface of topological Dirac semimetals, demonstrating robustness against disorder and potential for spintronics applications.

Contribution

It introduces a novel mechanism for spin transport via TDSM surface states, showing universal, semi-quantized spin currents that are robust and insensitive to microscopic details.

Findings

Surface spin current is semi-quantized and universal.

Spin current is robust against disorder.

Long-range spin transport is achievable on TDSM surfaces.

Abstract

We theoretically propose the long-range spin transport mediated by the gapless surface states of topological Dirac semimetal (TDSM). Low-dissipation spin current is a building block of next-generation spintronics devices. While conduction electrons in metals and spin waves in ferromagnetic insulators (FMIs) are the major carriers of spin current, their propagation length is inevitably limited due to the Joule heating or the Gilbert damping. In order to suppress dissipation and realize long-range spin transport, we here make use of the spin-helical surface states of TDSMs, such as $\mathrm{Cd_3 As_2}$ and $\mathrm{Na_3 Bi}$, which are robust against disorder. Based on a junction of two FMIs connected by a TDSM, we demonstrate that the magnetization dynamics in one FMI induces a spin current on the TDSM surface flowing to the other FMI. By both the analytical transport theory on the surface and the numerical simulation of real-time evolution in the bulk, we find that the induced spin current takes a universal semi-quantized value that is insensitive to the microscopic coupling structure between the FMI and the TDSM. We show that this surface spin current is robust against disorder over a long range, which indicates that the TDSM surface serves as a promising system for realizing spintronics devices.