Mode-Dependent Damping in Metallic Antiferromagnets Due to Inter-Sublattice Spin Pumping

TL;DR

This paper investigates the damping mechanisms in metallic antiferromagnets, revealing that the damping related to magnetization motion is significantly larger than that related to Ne9el order variation, challenging previous assumptions.

Contribution

It provides the first-principles calculation of damping parameters in antiferromagnetic materials, highlighting the dominant mode-dependent damping effects.

Findings

Damping coefficient for magnetization motion ($\alpha_m$) is 10-1000 times larger than for Ne9el order ($\alpha_n$).

Mode-dependent damping in antiferromagnets is significant and differs from ferromagnetic damping.

Contrasts with previous literature assumptions about damping uniformity.

Abstract

Damping in magnetization dynamics characterizes the dissipation of magnetic energy and is essential for improving the performance of spintronics-based devices. While the damping of ferromagnets has been well studied and can be artificially controlled in practice, the damping parameters of antiferromagnetic materials are nevertheless little known for their physical mechanisms or numerical values. Here we calculate the damping parameters in antiferromagnetic dynamics using the generalized scattering theory of magnetization dissipation combined with the first-principles transport computation. For the PtMn, IrMn, PdMn and FeMn metallic antiferromagnets, the damping coefficient associated with the motion of magnetization ($\alpha_m$) is one to three orders of magnitude larger than the other damping coefficient associated with the variation of the N\'eel order ($\alpha_n$), in sharp contrast to the assumptions made in the literature.