Ultrafast enhancement of interfacial exchange coupling in ferromagnetic bilayer

TL;DR

This paper demonstrates ultrafast, photo-enhanced interfacial exchange coupling in ferromagnetic bilayers, enabling efficient spin manipulation at low laser fluence and room temperature, advancing ultrafast spintronics technology.

Contribution

It introduces a novel optical method to significantly enhance interfacial exchange interactions in ferromagnetic bilayers, revealing new pathways for ultrafast, low-power spin control.

Findings

Photo-enhanced exchange interaction is 30-40 times more efficient than in non-magnetic layers.

Coherent spin precessions are observed to persist at room temperature.

The enhancement mechanism involves charge transfer between ferromagnetic layers.

Abstract

Fast spin manipulation in magnetic heterostructures, where magnetic interactions between different materials often define the functionality of devices, is a key issue in the development of ultrafast spintronics. Although recently developed optical approaches such as ultrafast spin-transfer and spin-orbit torques open new pathways to fast spin manipulation, these processes do not fully utilize the unique possibilities offered by interfacial magnetic coupling effects in ferromagnetic multilayer systems. Here, we experimentally demonstrate ultrafast photo-enhanced interfacial exchange interactions in the ferromagnetic Co$_2$FeAl/(Ga,Mn)As system at low laser fluence levels. The excitation efficiency of Co$_2$FeAl with the (Ga,Mn)As layer is 30-40 times higher than the case with the GaAs layer at 5 K due to a photo-enhanced exchange coupling interaction via photoexcited charge transfer between the two ferromagnetic layers. In addition, the coherent spin precessions persist to room temperature, excluding the drive of photo-enhanced magnetization in the (Ga,Mn)As layer and indicating a proximity-effect-related optical excitation mechanism. The results highlight the importance of considering the range of interfacial exchange interactions in ferromagnetic heterostructures and how these magnetic coupling effects can be utilized for ultrafast, low-power spin manipulation.