Two-dimensional flat band on the (011) surface of UTe2: Implication for STM measurements with a superconducting tip
Abstract
Scanning tunneling microscopy (STM) measurements have been extensively performed on the easily cleavable (011) surface of UTe2, using both normal-metal and superconducting tips. Motivated by these experiments, we theoretically investigate the topological surface states on the (011) surface of UTe2. We find that a two-dimensional nearly flat band emerges in the B3u state, giving rise to a pronounced zero-energy peak in the surface density of states. This flat band is supported by two key mechanisms: (i)~nontrivial Berry phases defined at multiple momenta give rise to low-energy in-gap states, and (ii)~weak spin conservation allows the gap function to acquire phase winding. Furthermore, to investigate the relation between the zero-bias peak observed in recent STM experiments with a superconducting tip and the topological surface states, we calculate the nonequilibrium dc tunneling current in a junction between an s-wave superconductor and the (011) surface of UTe2. Our results provide crucial insights into the superconducting pairing symmetry realized in UTe2.
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