Tuning the band topology of GdSb by epitaxial strain
Hadass S. Inbar, Dai Q. Ho, Shouvik Chatterjee, Aaron N. Engel, S. Khalid, Connor P. Dempsey, Mihir Pendharkar, Yu Chang, Shinichi Nishihaya, А. В. Федоров, Dong-Hui Lu, Makoto Hashimoto, Dan Read, Anderson Janotti, C. J. Palmstrøm
Abstract
Rare-earth monopnictide (RE-V) semimetal crystals subjected to hydrostatic pressure have shown interesting trends in magnetoresistance, magnetic ordering, and superconductivity, with theory predicting pressure-induced band inversion. Yet, thus far, there have been no direct experimental reports of interchanged band order in RE-Vs due to strain. This work studies the evolution of band topology in biaxially strained GdSb(001) epitaxial films using angle-resolved photoemission spectroscopy (ARPES) and density functional theory (DFT). As biaxial strain is tuned from tensile to compressive strain, the gap between the hole and the electron bands dispersed along [001] decreases. The conduction and valence band shifts seen in DFT and ARPES measurements are explained by a tight-binding model that accounts for the orbital symmetry of each band. Finally, we discuss the effect of biaxial strain on carrier compensation and magnetic ordering temperature.