Modulation of superconductivity by quantum confinement in doped strontium titanate

Abstract

Quantum confinement in a thin-film geometry offers viable routes for tuning the critical properties of superconductors through modification of both density of states and pairing interaction. Low-density systems like doped strontium titanate are especially susceptible to these confinement-induced effects. In this paper, we show that the superconducting critical temperature Tc is enhanced through quantum confinement in SrTiO3/SrTi1-xNbxO3/SrTiO3 heterostructures at x=1\% concentration, by measuring resistivity transitions and the Hall carrier density for different thicknesses of the doped layer. We observe a nonmonotonic raise of Tc with decreasing layer thickness at constant carrier density as estimated from the Hall effect. We analyze the results by solving a two-band model with a pairing interaction reproducing the density-dependent Tc of doped SrTiO3 in the bulk, that we confine to a potential well established self-consistently by the charged Nb dopants. The evolution of the theoretical Tc with thickness agrees well with experiments. We point out the possible role of density inhomogeneities and suggest novel methods for engineering superconductivity in epitaxial thin films.