Epitaxial Heusler Superlattice Co2MnAl/Fe2MnAl with Perpendicular Magnetic Anisotropy and Termination-Dependent Half-Metallicity

TL;DR

This study demonstrates the successful growth of epitaxial Heusler superlattices with perpendicular magnetic anisotropy and high spin polarization, revealing their potential for spintronic applications.

Contribution

It reports the first successful epitaxial growth of Co2MnAl/Fe2MnAl superlattices with controlled properties and enhanced spin polarization compared to single films.

Findings

Superlattices exhibit perpendicular magnetic anisotropy.

High spin polarization of 95% achieved in Co2MnAl terminated superlattices.

Out-of-plane spin reorientation transition occurs below 200 K.

Abstract

Single-crystal Heusler atomic-scale superlattices that have been predicted to exhibit perpendicular magnetic anisotropy and half-metallicity have been successfully grown by molecular beam epitaxy. Superlattices consisting of full-Heusler Co$_2$MnAl and Fe$_2$MnAl with one to three unit cell periodicity were grown on GaAs (001), MgO (001), and Cr (001)/MgO (001). Electron energy loss spectroscopy maps confirmed clearly segregated epitaxial Heusler layers with high cobalt or high iron concentrations for samples grown near room temperature on GaAs (001). Superlattice structures grown with an excess of aluminum had significantly lower thin film shape anisotropy and resulted in an out-of-plane spin reorientation transition at temperatures below 200 K for samples grown on GaAs (001). Synchrotron-based spin resolved photoemission spectroscopy found that the superlattice structure improves the Fermi level spin polarization near the X point in the bulk Brillouin zone. Stoichiometric Co$_2$MnAl terminated superlattice grown on MgO (001) had a spin polarization of 95%, while a pure Co$_2$MnAl film had a spin polarization of only 65%.