Electronic and magnetic properties of the topological semimetal SmMg2Bi2

Abstract

Dirac semimetals show nontrivial physical properties and can host exotic quantum states like Weyl semimetals and topological insulators under suitable external conditions. Here, by combining angle-resolved photoemission spectroscopy measurements (ARPES) and first-principle calculations, we demonstrate that Zintl-phase compound SmMg2Bi2 belongs to the close proximity to a topological Dirac semimetallic state. ARPES results show a Dirac-like band crossing at the zone-center near the Fermi level (E F) which is further confirmed by first-principle calculations. Theoretical studies also reveal that SmMg2Bi2 belongs to a Z2 topological class and hosts spin-polarized states around the E F. Zintl's theory predicts that the valence state of Sm in this material should be Sm2+, however we detect many Sm-4f multiplet states (flat-bands) whose energy positions suggest the presence of both Sm2+ and Sm3+. It is also evident that these flat-bands and other dispersive states are strongly hybridized when they cross each other. Due to the presence of Sm3+ ions, the temperature dependence of magnetic susceptibility (T) shows Curie-Weiss-like contribution in the low temperature region, in addition to the Van Vleck-like behaviour expected for the Sm2+ ions. The present study will help in better understanding of the electronic structure, magnetism and transport properties of related materials.