Abstract
The surface structural, transport, and magnetic properties of superlattice films were examined, focusing on the effects of the superlattice periodicity of (Fe3O4/MgO) layers. The superlattice structures of (Fe3O4/MgO)(n) ultrathin films were fabricated using molecular-beam epitaxy on MgO(001) substrates, where n is the number of layers. It was observed that these oxide films have a single crystalline quality with the same orientation as the substrates for Fe3O4 as thin as approximately three unit cells. The transport and magnetic results showed that the conductivity and magnetization of the superlattice increase as the number of (Fe3O4/MgO) layers is increased. Furthermore, a sharp Verwey transition was found in the (Fe3O4/MgO)(n) superlattices with thickness layer smaller than seen in an earlier study for a single or superlattice film. These results give the indication that Fe3O4 superlattice ultrathin films have better properties than single layers of the same thickness. This artificial growth of superlattice ultrathin films will provide a useful method to realize novel properties for other complex oxide systems.