Topological surface states in the Kondo insulator Yb B12 revealed via planar tunneling spectroscopy

A. Gupta, A. Weiser, L. Pressley, Y. Luo, C. Lygouras, J. Trowbridge, W. A. Phelan, C. L. Broholm, T. M. McQueen, W. K. Park

Research output: Contribution to journalArticlepeer-review

2 Scopus citations

Abstract

Planar tunneling spectroscopy of the Kondo insulator SmB6 suggests that an interaction between the surface Dirac fermions and the bulk spin excitons results in incompletely protected topological surface states. To gain further insight into their true nature, it is necessary to study other topological Kondo insulator candidates. Calculations of electronic energy bands predict that the Kondo insulator YbB12 hosts topological surface states protected by crystalline mirror symmetry. In this study, we present tunneling conductance spectra obtained from the (001) surface of YbB12 single crystals and discuss them in comparison to SmB6. The linear conductance at low bias provides strong evidence for the existence of surface Dirac fermions. The double-hump structure in the negative-bias region is associated with hybridized band edges, in agreement with a calculated band structure. While these similarities with SmB6 are suggestive of the existence of topological surface states in YbB12, in agreement with other experiments, some discrepancies are also observed, which we attribute to a difference in their exact nature from those in SmB6.

Original languageEnglish
Article number165132
JournalPhysical Review B
Volume107
Issue number16
DOIs
StatePublished - Apr 15 2023

Funding

The work at NHMFL and FSU was supported by Grants No. NSF/DMR-2003405, No. NSF/DMR-1644779, and the State of Florida. The work at JHU was funded by Grant No. DOE/BES EFRC DE-SC0019331, JHU Catalyst Fund, and Grant No. NSF/DMR(PARADIM)-2039380.

FundersFunder number
JHU Catalyst Fund-2039380
State of FloridaDOE/BES EFRC DE-SC0019331

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