Magnon transport in the presence of antisymmetric exchange in a weak antiferromagnet

The Dzyaloshinskii-Moriya interaction (DMI) is at the heart of many modern developments in the research field of spintronics. DMI is known to generate noncollinear magnetic textures, and can take two forms in antiferromagnets: homogeneous or inter-sublattice, leading to small, canted moments and inhomogeneous or intra-sublattice, leading to formation of chiral structures. In this work, we first determine the strength of the effective field created by the DMI, using SQUID based magnetometry and transport measurements, in thin films of the antiferromagnetic iron oxide hematite, alpha-Fe2O3. We demonstrate that DMI additionally introduces reconfigurability in the long distance magnon transport in these films under different orientations of a magnetic field. This arises as a hysteresis centred around the easy-axis direction for an external field rotated in opposing directions whose width decreases with increasing magnetic field as the Zeeman energy competes with the effective field created by the DMI.

Automated summary

The Dzyaloshinskii-Moriya interaction (DMI) is crucial in spintronics, generating noncollinear magnetic textures and introducing reconfigurability in long distance magnon transport, as demonstrated in thin films of α-Fe2O3. This effect is hysteresis centered around the easy-axis direction for an external field rotated in opposing directions, with the width decreasing as the Zeeman energy competes with the effective field created by the DMI.