Light-induced ultrafast magnetization dynamics in van der Waals antiferromagnetic CrSBr

TL;DR

This study uses real-time density functional theory to explore how ultrafast laser pulses influence magnetization in CrSBr, revealing mechanisms for magnetic control and coherent magnon excitation in van der Waals antiferromagnets.

Contribution

It demonstrates how laser pulses of different intensities and magnetic fields can control magnetization dynamics and excite coherent magnons in CrSBr at femtosecond timescales.

Findings

Low-fluence pulses enhance magnetic moments via spin transfer.

High-fluence pulses cause demagnetization and Neel vector reduction.

Magnetic field enables ultrafast reorientation and coherent magnon excitation.

Abstract

We investigate the ultrafast magnetization dynamics of semiconducting antiferromagnetic CrSBr using real-time time-dependent density functional theory. In zero magnetic field, laser excitation modifies only the magnetization along the easy axis, leaving transverse components unaffected. We find that below-gap, low-fluence pulses enhance the local magnetic moments via spin transfer from nonmagnetic to magnetic atoms, increasing the Neel vector. In contrast, high-fluence pulses drive interlayer spin transfer between magnetic atoms, producing strong demagnetization and reducing the Neel vector, while S and Br atoms exhibit primarily charge transfer with weak opposite contribution to the demagnetization. An applied magnetic field qualitatively alters the response, enabling both magnitude changes and ultrafast reorientation of the magnetization. We show that the resulting layer-resolved reorientation respects a twofold rotation about the x-axis, exciting coherent optical magnons even under this symmetry, which modulate the relative angle between neighboring layers and periodically tune electronic properties. These results reveal a microscopic pathway for coherent magnon excitation in van der Waals magnets and establish a framework for controlling their coupled spin-charge dynamics on femtosecond timescales.