Growth and characterization of quaternary-alloy ferromagnetic semiconductor (In,Ga,Fe)Sb

Abstract

We study the growth and properties of the quaternary-alloy ferromagnetic semiconductor (In0.94-x,Gax,Fe0.06)Sb (x = 5%-30%; the Fe concentration is fixed at 6%) grown by low-temperature molecular beam epitaxy. Reflection high-energy electron diffraction patterns, scanning transmission electron microscopy lattice images, and X-ray diffraction spectra indicate that the (In0.94-x,Gax,Fe0.06)Sb layers have a zinc blende crystal structure without any other second phase. The lattice constant of the (In0.94-x,Gax,Fe0.06)Sb films changes linearly with the Ga concentration x, indicating that Ga atoms substitute In atoms in the zinc-blende structure. We found that the carrier type of (In0.94-x,Gax,Fe0.06)Sb can be systematically controlled by varying x, being n-type when x ≤ 10% and p-type when x ≥ 20%. Characterization studies using magnetic circular dichroism spectroscopy indicate that the (In0.94-x,Gax,Fe0.06)Sb layers have intrinsic ferromagnetism with relatively high Curie temperatures (TC = 40-120 K). The ability to widely control the fundamental material properties (lattice constant, bandgap, carrier type, and magnetic property) of (In0.94-x,Gax,Fe0.06)Sb demonstrated in this work is essential for spintronic device applications.