Two-dimensional Shiba lattices as possible platform for crystalline topological superconductivity

TL;DR

This study demonstrates that two-dimensional Shiba lattices, created with atomic precision, can host various topological superconducting phases with protected boundary modes, offering a new platform for designing topological quantum materials.

Contribution

The paper shows that engineered Shiba lattices can realize mirror symmetry protected topological superconductors with distinct boundary states, advancing the design of topological quantum systems.

Findings

Identification of edge modes and higher-order corner states in Shiba lattices.

Observation of symmetry-protected bulk nodal points.

Potential to control topological phases via lattice geometry.

Abstract

Localized or propagating Majorana boundary modes are the key feature of topological superconductors. They are rare in naturally-occurring compounds, but the tailored manipulation of quantum matter offers opportunities for their realization. Specifically, lattices of Yu-Shiba-Rusinov bound states $-$ Shiba lattices $-$ that arise when magnetic adatoms are placed on the surface of a conventional superconductor can be used to create topological bands within the superconducting gap of the substrate. Here, using scanning tunnelling microscopy to create and probe adatom lattices with single atom precision we reveal two signatures consistent with the realization of two types of mirror symmetry protected topological superconductors. The first has edge modes as well as higher-order corner states, and the second has symmetry-protected bulk nodal points. In principle, their topological character and boundary modes should be protected by the spatial symmetries of the adatom lattice. Our results highlight the potential of Shiba lattices as a platform to design the topology and sample geometry of 2D superconductors.