Femtosecond all-optical coherent control of spin polarization in altermagnets

TL;DR

This study demonstrates femtosecond all-optical control of spin polarization in altermagnets, revealing transient spin-polarized surface states in RuO2 through ultrafast Kerr effect measurements.

Contribution

It provides experimental evidence of coherent spin responses and transient surface states in altermagnets using ultrashort laser pulses.

Findings

Ultrafast Kerr rotation shows a coherent contribution lasting about 200 fs.

Transient spin-polarized surface states are observed in RuO2.

Distinct spin dynamics differ from conventional ferromagnets.

Abstract

Altermagnets constitute an emerging materials platform for spintronic technologies by combining compensated magnetic order with ferromagnet-like spin-split electronic bands. Here, we investigate the proposed d-wave altermagnetic material RuO2 using circularly polarized ultrashort laser pulses. Time-resolved magneto-optical Kerr effect measurements, which are intrinsically sensitive to surface and interface states, reveal the ultrafast spin response of RuO2. In contrast to the demagnetization dynamics characteristic of conventional ferromagnets, we observe a distinct coherent contribution to the complex Kerr rotation that appears during the light-matter interaction and lasts for about 200 fs. Similar signatures have been associated with spin-momentum locking and directional band splitting in spin-split surface states of topological insulators as well as spin-orbit-coupled semiconductors. They are governed by a finite Raman coherence time. We interpret this coherent response as evidence for transient spin-polarized surface states in RuO2, consistent with the emergence of altermagnetic surface states that are directly relevant to spin-polarized transport at surfaces and interfaces.