Magnetizing altermagnets by ultrafast asymmetric spin dynamics

Abstract

Laser pulses are known to induce symmetric demagnetization: equal loss of magnetic moments in the identical sublattices of antiferromagnets and ferromagnets at ultrashort timescales. Using time-dependent density functional theory, we show that linearly polarized laser pulses can drive asymmetric demagnetization between otherwise identical sublattices in the d-wave compensated altermagnet (AM) RuO2, resulting in a photo-induced ferrimagnetic state with a strong net magnetization of 0.2 μB per unit cell. The sign and magnitude of this metastable magnetization are highly controllable by laser polarization. We identify polarization-selective asymmetric optical intersite spin transfer (a-OISTR) as the primary mechanism generating the net moment, followed by asymmetric spin flips (a-SF) that further amplifies it. Both effects originate from the characteristic nodal spin band topology of d-wave AMs. Moreover, we demonstrate that this laser-induced magnetization is universal across various d-wave AMs, including experimentally confirmed KV2Se2O and RbV2Te2O. We uncover a robust route to light-controlled magnetization in AMs on ultrafast timescales.