Anisotropic magnetotransport realized in doped hematite

Conventional antiferromagnetic materials have long been recognized for their time-reversal symmetry, resulting in a zero anomalous Hall coefficient. However, a paradigm shift occurs when examining easy-axis antiferromagnets and their spin-flop transition. This transition introduces a magnetic canted moment, leading to the emergence of a non-zero anomalous Hall signal and the generation of a non-dissipative transversal current. While high symmetry systems typically manifest an isotropic Hall effect, our study unveils the extraordinary behavior exhibited by hematite that becomes conductive due to small Ti doping. We investigate the magnetotransport in Titanium-doped hematite, uncovering a highly pronounced and unconventional symmetry. Notably, this effect displays a remarkable dependence on the crystal orientation of the material. We establish a compelling correlation between our experimental observations and the predicted anomalous Hall effect in altermagnets through symmetry analysis. This study expands our understanding of the Hall effect in antiferromagnetic materials and sheds light on the intricate interplay between crystal orientation and unconventional Hall phenomena

Anisotropic long-range spin transport in canted antiferromagnetic orthoferrite YFeO3

International audienceIn antiferromagnets, the efficient propagation of spin-waves has until now only been observed in the insulating antiferromagnet hematite, where circularly (or a superposition of pairs of linearly) polarized spin-waves propagate over long distances. Here, we report long-distance spin-transport in the antiferromagnetic orthoferrite YFeO3, where a different transport mechanism is enabled by the combined presence of the Dzyaloshinskii-Moriya interaction and externally applied fields. The magnon decay length is shown to exceed hundreds of nano-meters, in line with resonance measurements that highlight the low magnetic damping. We observe a strong anisotropy in the magnon decay lengths that we can attribute to the role of the magnon group velocity in the propagation of spin-waves in antiferromagnets. This unique mode of transport identified in YFeO3 opens up the possibility of a large and technologically relevant class of materials, i.e., canted antiferromagnets, for long-distance spin transport

Anisotropic long-range spin transport in canted antiferromagnetic orthoferrite YFeO3

International audienceIn antiferromagnets, the efficient propagation of spin-waves has until now only been observed in the insulating antiferromagnet hematite, where circularly (or a superposition of pairs of linearly) polarized spin-waves propagate over long distances. Here, we report long-distance spin-transport in the antiferromagnetic orthoferrite YFeO3, where a different transport mechanism is enabled by the combined presence of the Dzyaloshinskii-Moriya interaction and externally applied fields. The magnon decay length is shown to exceed hundreds of nano-meters, in line with resonance measurements that highlight the low magnetic damping. We observe a strong anisotropy in the magnon decay lengths that we can attribute to the role of the magnon group velocity in the propagation of spin-waves in antiferromagnets. This unique mode of transport identified in YFeO3 opens up the possibility of a large and technologically relevant class of materials, i.e., canted antiferromagnets, for long-distance spin transport