Spin current generation from an epitaxial tungsten dioxide WO2

We report on efficient spin current generation at room temperature in rutile-type WO2 grown on an Al2O3(0001) substrate. The optimal WO2 film has a (010)-oriented monoclinically distorted rutile structure with metallic conductivity due to 5d(2) electrons, as characterized by x-ray diffraction, electronic transport, and x-ray photoelectron spectroscopy. By conducting harmonic Hall measurement in a Ni81Fe19/WO2 bilayer, we estimate two symmetries of the spin-orbit torque (SOT), i.e., dampinglike (DL) and fieldlike ones, to find that the former is larger than the latter. By comparison with the Ni81Fe19/W control sample, the observed DL SOT efficiency ?(DL) of WO2 (+0.174) is about two-thirds of that of W (-0.281) in magnitude, with a striking difference in their signs. The magnitude of the ?(DL) of WO2 exhibits a comparable value to those of widely reported Pt and Ta, and Ir oxide IrO2. The positive sign of the ?(DL) of WO2 can be explained by the preceding theoretical study based on the 4d oxides. These results highlight that the epitaxial WO2 offers a great opportunity of rutile oxides with spintronic functionalities, leading to future spin-orbit torque-controlled devices.

Automated summary

We report on the generation of efficient spin current in rutile-type WO2 at room temperature. The WO2 film is characterized by its metallic conductivity and monoclinically distorted rutile structure. By conducting measurements, we find that the dampinglike spin-orbit torque (SOT) in WO2 is larger than the fieldlike one, and the efficiency of WO2 is about two-thirds of that of W. The positive sign of the dampinglike SOT in WO2 can be explained by preceding theoretical studies.