Abstract
Low power spintronic devices based on the propagation of pure magnonic spin currents in antiferromagnetic insulator materials offer several distinct advantages over ferromagnetic components including higher frequency magnons and a stability against disturbing external magnetic fields. In this work, we make use of the insulating antiferromagnetic phase of iron oxide, the mineral hematite $\alpha$-Fe$_2$O$_3$ to investigate the long distance transport of thermally generated magnonic spin currents. We report on the excitation of magnons generated by the spin Seebeck effect, transported both parallel and perpendicular to the antiferromagnetic easy-axis under an applied magnetic field. Making use of an atomistic hematite toy model, we calculate the transport characteristics from the deviation of the antiferromagnetic ordering from equilibrium under an applied field. We resolve the role of the magnetic order parameters in the transport, and experimentally we find significant thermal spin transport without the need for a net magnetization.
Highlights
The quanta of magnetic excitations, known as magnons, efficiently transport angular momentum in magnetic materials including ferromagnetic [1,2] and antiferromagnetic insulators (AFMI) [3,4,5]
We report on the excitation of magnons generated by the spin Seebeck effect, transported both parallel and perpendicular to the antiferromagnetic easy-axis under an applied magnetic field
If a heavy metal (HM) with a large spin orbit coupling is placed in contact with the AFMI, this magnon current can be converted to a charge current and detected due to the inverse spin Hall effect (ISHE) [3,8,10,15]
Summary
The quanta of magnetic excitations, known as magnons, efficiently transport angular momentum in magnetic materials including ferromagnetic [1,2] and antiferromagnetic insulators (AFMI) [3,4,5]. This means that S has contributions related to each order parameter; the Néel order spin Seebeck conductance Sn and the magnetic moment spin Seebeck conductance Sm [11,12] Each of these comes with additional transport and dissipation paths for thermally excited magnons and has a distinct field and temperature dependence [11,12]. In this work we demonstrate that the application of a magnetic field parallel to the easy-axis of a bulk crystal of the insulating antiferromagnetic iron oxide hematite (α-Fe2O3) elicits a nonlocal spin Seebeck effect mediated by the Néel vector. The Dzyaloshinskii-Moriya interaction (DMI), parallel to the c-axis is present in this material and leads to a reorientation of n under an applied field if a finite angle between H and the EA exists [28,29]
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