RKKY signals characterizing the topological phase transitions in Floquet Dirac semimetals

TL;DR

This paper proposes using RKKY interactions to detect topological phase transitions in Floquet Dirac semimetals, revealing distinct magnetic signals that characterize transitions between DSM, WSM, and WHM phases.

Contribution

It introduces a novel magnetic detection method based on RKKY interactions for identifying topological phase transitions in Floquet Dirac semimetals, highlighting magnetic filtering effects and robustness.

Findings

Detection of Ising term $J_I$ signals phase transition from DSM to WSM.

Magnetic filtering effect distinguishes WSM and WHM phases.

Robustness of magnetic signals against electron-hole symmetry breaking.

Abstract

Recently, the Floquet ${\rm Na_3Bi}$-type material has been proposed as an ideal platform for realizing various phases, i.e., the spin-degenerate Dirac semimetal (DSM) can be turned into the Weyl semimetal (WSM), and even to the Weyl half-metal (WHM). Instead of the conventional electrical methods, we use the RKKY interaction to characterize the topological phase transitions in this paper. It is found that detecting the Ising term $J_I$ is feasible for distinguishing the phase transition of DSM/WSM, since the emergence of $J_I$ is induced by the broken spin degeneracy. For the case with impurities deposited on $z$ axis (the line connecting the Weyl points), the Heisenberg term $J_H$ coexists with $J_I$ in the WSM, while $J_H$ is filtered out and only $J_I$ survives in the WHM. This magnetic filtering effect is a reflection of the fully spin-polarized property (one spin band is in the WSM phase while the other is gapped) of the WHM, and it can act a signal to capture the phase transition of WSM/WHM. This signal can not be disturbed unless the direction of the impurities greatly deviates from $z$ axis. Interestingly, as the impurities are moved into the $x$-$y$ plane, there arises another signal (a dip structure for $J_H$ at the phase boundary), which can also identify the phase transition of WSM/WHM. Furthermore, we have verified that all magnetic signals are robust to the term that breaks the electron-hole symmetry. Besides characterizing the phase transitions, our results also suggest that the Floquet DSMs are power platforms for controlling the magnetic interaction.