Tunable polar distortions and magnetism in GdxLa1-xPtSb epitaxial films

Abstract

Hexagonal ABC intermetallics are predicted to have tunable ferroelectric, topological, and magnetic properties as a function of the polar buckling of BC atomic planes. We report the impact of isovalent lanthanide substitution on the buckling, structural phase transitions, and electronic and magnetic properties of GdxLa1-xPtSb films grown by molecular beam epitaxy (MBE) on c-plane sapphire substrates. The GdxLa1-xPtSb films form a solid solution from x = 0 to 1 and retain the polar hexagonal structure (P63 mc) out to x ≤ 0.95. With increasing x, the PtSb buckling increases and the out of plane lattice constant c decreases due to the lanthanide contraction. While hexagonal LaPtSb is a highly conductive polar metal, the carrier density decreases with x until an abrupt phase transition to a zero band overlap semimetal is found for cubic GdPtSb at x=1. The magnetic susceptibility peaks at small but finite x, which we attribute to Ruderman Kittel Kasuya Yosida (RKKY) coupling between localized 4f moments, whose concentration increases with x, and free carriers that decrease with x. Samples with x≥ 0.3 show antiferromagnetic Curie-Weiss behavior and a Neel temperature that increases with x. The GdxLa1-xPtSb system provides opportunities to dramatically alter the polar buckling and concentration of local 4f moments, for tuning chiral spin textures and topological phases.