Spin and orbital magnetic moments in perpendicularly magnetized Ni1-xCo2+yO4-z epitaxial thin films: Effects of site-dependent cation valence states

Abstract

We carried out x-ray absorption spectroscopy (XAS) and x-ray magnetic circular dichroism (XMCD) spectroscopy and investigated cation valence states and spin and orbital magnetic moments in the inverse-spinel ferrimagnet Ni1-xCo2+yO4-z (NCO) epitaxial films with the perpendicular magnetic anisotropy. We show that the oxygen pressure PO2 during the film growth by pulsed laser deposition influences not only the cation stoichiometry (site-occupation) but also the cation valence state. Our XAS results show that the Ni in the Oh-site is in the intermediate valence state between +2 and +3, Ni(2+δ)+ (0<δ<1), whose nominal valence state (the δ value) varies depending on PO2. On the other hand, the Co in the octahedral (Oh) and tetrahedral (Td) sites respectively have the valence state close to +3 and +2. We also find that the XMCD signals originate mainly from the Td-site Co2+ (CoTd) and Oh-site Ni(2+δ)+ (NiOh), indicating that these cation valence states are the key in determining the magnetic and transport properties of NCO films. Interestingly, the valence state of Ni(2+δ)+ that gives rise to the XMCD signal remains unchanged independent of PO2. The electronic structure of Ni(2+δ)+ that is responsible for the magnetic moment and electrical conduction differs from those of Ni2+ and Ni3+. In addition, the orbital magnetic moment originating from CoTd is as large as 0.14 μB/CoTd and parallel to the magnetization while the NiOh orbital moment is as small as 0.07 μB/NiOh and is rather isotropic. The CoTd therefore plays the key role in the perpendicular magnetic anisotropy of the films. Our results demonstrate the significance of the site-dependent cations valence states for the magnetic and transport properties of NCO films.