Anomalous Hall conductivity and electronic structures of Si-substituted Mn2CoAl epitaxial films

Abstract

We study anomalous Hall conductivity (σ AHC) and electronic band structures of Si-substituted Mn2CoAl (Mn2CoAl1-xSix). First-principles calculations reveal that the electronic band structure is like a spin-gapless system even after substituting a quaternary element of Si for Al up to x = 0.2 in Mn2CoAl1-xSix. This means that the Si substitution enables the Fermi level shift without largely changing the electronic structures in Mn2CoAl. By using molecular beam epitaxy (MBE) techniques, Mn2CoAl1-xSix epitaxial films can be grown, leading to the systematic control of x (0 x 0.3). In addition to the electrical conductivity, the values of σ AHC for the Mn2CoAl1-xSix films are similar to those in Mn2CoAl films shown in previous reports. We note that a very small σ AHC of 1.1 S/cm is obtained for x = 0.225 and the sign of σ AHC is changed from positive to negative at around x = 0.25. We discuss the origin of the sign reversal of σ AHC as a consequence of the Fermi level shift in MCA. Considering the presence of the structural disorder in the Mn2CoAl1-xSix films, we can conclude that the small value and sign reversal of σ AHC are not related to the characteristics of spin-gapless semiconductors.