Emergent superconductivity in single crystalline MgTi2O4 films via structural engineering

Abstract

Spinel compounds have demonstrated rich functionalities but rarely shown superconductivity. Here, we report the emergence of superconductivity in the spinel MgTi2O4, known to be an insulator with a complicated order. The superconducting transition is achieved by engineering a superlattice of MgTi2O4 and SrTiO3. The onset transition temperature in the MgTi2O4 layer can be tuned from 0 to 5 K in such geometry, concurrently with a stretched c-axis (from 8.51 to 8.53 ) compared to the bulk material. Such a positive correlation without saturation suggests ample room for the further enhancement. Intriguingly, the superlattice exhibits isotropic upper critical field Hc2 that breaks the Pauli limit, distinct from the highly anisotropic feature of interface superconductivity. The origin of superconductivity in the MgTi2O4 layer is understood in combination with the electron energy loss spectra and the first-principles electronic structure calculations, which point to the birth of superconductivity in the MgTi2O4 layer by preventing the Ti-Ti dimerization. Our discovery not only provides a platform to explore the interplay between the superconductivity and other exotic states, but also opens a new window to realize superconductivity in the spinel compounds as well as other titanium oxides.