Origin of sublattice particle-hole asymmetry in monolayer FeSe superconductors

TL;DR

This paper investigates the origin of particle-hole asymmetry between Fe sublattices in monolayer FeSe superconductors, highlighting the roles of substrate-induced symmetry breaking and odd-frequency pairing correlations.

Contribution

It identifies substrate nematic symmetry breaking as key to the asymmetry and proposes a nodeless d-wave gap mechanism as the most physical explanation.

Findings

Enhanced asymmetry observed at nematic domain walls

Substrate symmetry breaking influences the superconducting gap

Evidence of odd-frequency pairing correlations

Abstract

In iron-based superconductors, the two Fe atoms in the unit cell are typically related by crystal symmetries; therefore, we expect no intra-unit cell variations in the superconducting gap. However, recent experiments have challenged this expectation, reporting intra-unit cell variations in the gap with an unusual particle-hole asymmetry. Here, we examine the origin of this asymmetry between the two Fe sublattices in monolayer FeSe grown on SrTiO$_3$. We reveal that, in addition to the substrate-induced broken inversion symmetry, substrate nematic symmetry breaking is key to observing this asymmetry. We further identify two possible mechanisms through which this can occur. The first is through an odd-parity gap function that coexists with an extended $s$-wave function. The second is via a nodeless $d$-wave gap function that develops in the presence of a symmetry-breaking substrate. We argue that the latter mechanism is more physical. To test our theory, we performed scanning tunneling spectroscopy measurements across the nematic domain walls, which exhibit a clear enhancement of the asymmetry between the two Fe sublattices. In addition, we reveal that the observed sublattice particle-hole asymmetry is associated with odd-frequency pairing correlations, providing an experimental realization of this unusual pairing correlation.