We have investigated the interfacial structure and its correlation with the calculated spin polarization in Co 2 MnSi/GaAs(001) lateral spin valves. Co 2 MnSi (CMS) films were grown on As-terminated c(4x4) GaAs(100) by molecular beam epitaxy using different first atomic layers: MnSi, Co, and Mn. Atomically-resolved Z-contrast scanning transmission electron microscopy (STEM) imaging and electron energy loss spectroscopy (EELS) were used to develop atomic structural models of the CMS/GaAs interfaces that were used as inputs for first principles calculations to understand the magnetic and electronic properties of the interface. First principles structures were relaxed and then validated by comparing experimental and simulated highresolution STEM images. STEM-EELS results show that all three films have similar six atomic layer thick, Mn and As rich multilayer interfaces. However, the Co-initiated interface contains a Mn 2 As-like layer, which is antiferromagnetic, and which is not present in the other two interfaces. Density functional theory calculations show a higher degree of interface spin polarization in the Mn-and MnSi-initiated cases, compared to the Co-initiated case, although none of the interfaces are half metallic. The loss of half-metallicity is attributed, at least in part, to the segregation of Mn at the interface which leads to the formation of interface states. The implications for the performance of lateral spin valves based on these interfaces are discussed briefly.
We show that when two Heusler alloys are layered in the [001], [110], or [111] directions for various thicknesses to form a superlattice, the Slater-Pauling rule may still be satisfied and the resulting superlattice is often half-metallic with gaps comparable to or larger than those of its constituents. In addition, uniaxial magnetocrystalline anisotropy is induced because of the differences in the electronic structure of the two Heuslers in the superlattice. Various full-full, full-half, and half-half Heusler superlattices are studied, and potential half-metallic superlattices with perpendicular magnetocrystalline anisotropy are identified.
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