The importance of Charge Fluctuations for the Topological Phase in SmB6

Abstract

The discovery of topologically non-trivial states in band insulators has induced an extensive search for topological phase in strongly correlated electron systems. In particular, samarium hexaboride (SmB6) has drawn much attention as it might represent a new class of condensed matter called topological Kondo insulator. Kondo insulators (KI) can have non-trivial Z2 topology because the energy gap opens at the Fermi energy (EF) by hybridization between an odd- parity renormalized f band and an even- parity conduction d band. However, the characteristics of SmB6 deviate from the conventional KI because its gap is insensitive to doping and pressure. Thus, it is unclear what makes the gap of SmB6 different from that of KI, and how the band inversion features occur. In this manuscript, we demonstrate the importance of charge fluctuations in SmB6. Our angle-resolved photoemission spectroscopy (ARPES) results reveal that with decreasing temperature the bottom of the d-f hybridized band at the X point gradually shifts from below to above EF. This shift accompanies a redistribution of spectral weight from the upper to the lower quasiparticle band, and reflects the change in both carrier density and the number of localized f electron. Moreover, because this hybridized band is predicted to have odd parity and to induce a non-trivial Z2 topology, we compare our ARPES spectra with theoretical surface band structures and find signatures of topological surface states. Therefore, our results indicate that SmB6 is a charge fluctuating topological insulator having the odd-parity hybridized band above EF at the X point. This demonstrates that the charge fluctuations do not only drive the insulating bulk phase but also the non-trivial topological phase.