Abstract
LaAlO3/SrTiO3 interfaces are a nice example of a two-dimensional electron gas, whose carrier density can be varied by top- and back-gating techniques. Due to the electron confinement near the interface, the two-dimensional band structure is split into sub-bands, and more than one sub-band can be filled when the carrier density increases. These interfaces also host superconductivity, and the interplay of two-dimensionality, multi-band character, with the possible occurrence of multi-gap superconductivity and disorder calls for a better understanding of finite-bandwidth effects on the superconducting critical temperature of heavily disordered multi-gap superconductors.
Highlights
IntroductionPublisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations
Several theoretical concepts have been introduced to describe the non-monotonic behavior of the superconducting critical temperature at oxide interfaces as a function of the carrier concentration, highlighting, for example, the role of electron–electron correlations and spin–orbit interactions [14,24], or of the extended s-wave pairing symmetry [25]
Our scope was to highlight the role of disorder and inter-band scattering in the suppression of the superconducting critical temperature
Summary
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