Elsa Prada

Full-shell nanowires are hybrid nanostructures consisting of a semiconducting core encapsulated in an epitaxial superconducting shell. When subject to an external magnetic flux, they exhibit the Little-Parks (LP) phenomenon of flux-modulated superconductivity, an effect connected to the physics of Abrikosov vortex lines in type-II superconductors. We show that full-shell nanowires can host subgap states that are a variant of the Caroli-de Gennes-Matricon (CdGM) states in vortices. These CdGM analogs are in fact shell-induced Van Hove singularities in propagating core subbands. We elucidate their structure, parameter dependence and behavior in tunneling spectroscopy through a series of models of growing complexity. We show through microscopic numerical simulations that they exhibit a characteristic skewness towards high magnetic fields inside non-zero LP lobes resulting from the interplay of three ingredients. First, core subbands exhibit a diamagnetic response, so that they disperse with flux depending on their generalized angular momentum. Second, the band bending at the core/shell interface induces a ring-like profile on the CdGM analog state wavefunctions with average radius smaller than the core radius. And last, degeneracy points emerge where all the CdGM Van Hove singularities coalesce. This happens when the flux threading each wavefunction is equal to an integer multiple of the flux quantum, a condition that shifts the degeneracy points away from the center of the LP lobes, skewing the CdGM analogs. Our analysis unlocks a transparent analytical description that allows to extract precise microscopic information about the nanowire by measuring the energy and skewness of CdGM analogs.