Half-Metallic Ferromagnetism in the Heusler Compound Co2FeSi revealed by Resistivity, Magnetoresistance, and Anomalous Hall Effect measurements

Abstract

We present electrical transport data for single-crystalline Co2FeSi which provide clear-cut evidence that this Heusler compound is truly a half-metallic ferromagnet, i.e. it possesses perfect spin-polarization. More specifically, the temperature dependence of is governed by electron scattering off magnons which are thermally excited over a sizeable gap ≈ 100 K ( 9 meV) separating the electronic majority states at the Fermi level from the unoccupied minority states. As a consequence, electron-magnon scattering is only relevant at T but freezes out at lower temperatures, i.e., the spin-polarization of the electrons at the Fermi level remains practically perfect for T. The gapped magnon population has a decisive influence on the magnetoresistance and the anomalous Hall effect (AHE): i) The magnetoresistance changes its sign at T 100 K, ii) the anomalous Hall coefficient is strongly temperature dependent at T 100 K and compatible with Berry phase related and/or side-jump electronic deflection, whereas it is practically temperature-independent at lower temperatures.