Structural ordering driven anisotropic magnetoresistance, anomalous Hall resistance and its topological overtones in full-Heusler Co2MnSi thin films

Abstract

We report the evolution of crystallographic structure, magnetic ordering and electronic transport in thin films of full-Heusler alloy Co2MnSi deposited on (001) MgO with annealing temperatures (TA). By increasing the TA from 300 to 600, the film goes from a disordered nanocrystalline phase to B2 ordered and finally to the L21 ordered alloy. The saturation magnetic moment improves with structural ordering and approaches the Slater-Pauling value of ≈ 5.0 μB per formula unit for TA = 600. At this stage the films are soft magnets with coercive and saturation fields as low as ≈ 7 mT and 350 mT, respectively. Remarkable effects of improved structural order are also seen in longitudinal resistivity (xx) and residual resistivity ratio. A model based upon electronic transparency of grain boundaries illucidates the transition from a state of negative d/dT to positive d/dT with improved structural order. The Hall resistivity (xy) derives contribution from the normal scattering of charge carriers in external magnetic field, the anomalous effect originating from built-in magnetization and a small but distinct topological Hall effect in the disordered phase. The carrier concentration (n) and mobility (μ) have been extracted from the high field xy data. The highly ordered films are characterized by n and μ of 1.19× 1029 m-3 and 0.4 cm2V-1s-1 at room temperature. The dependence of xy on xx indicates the dominance of skew scattering in our films, which shows a monotonic drop on raising the TA. The topological Hall effect is analyzed for the films annealed at 300. ......