Superconducting stripes induced by ferromagnetic proximity in an oxide heterostructure

TL;DR

This study discovers a novel spatially-varying superconducting state with stripe-like features at the interface of a ferromagnetic oxide heterostructure, influenced by band filling and magnetic proximity effects.

Contribution

It reports the first observation of superconducting stripes induced by ferromagnetic proximity in an oxide heterostructure, revealing anisotropic superconductivity linked to carrier density and magnetic coupling.

Findings

Superconducting stripes with phase coherence form at the interface.

Anisotropic Tc and Hc2 observed in low-carrier-density samples.

Superconductivity becomes isotropic at high carrier density.

Abstract

The intimate connection between magnetism and superconducting pairing routinely plays a central role in determining the occurrence of unconventional superconducting states. In high-transition-temperature (high-Tc) stripe-ordered cuprate superconductors and a magnetically ordered iron-based superconductor, the coupling between magnetism and superconductivity gives birth to novel phases of matter with modulation of the superconducting pairing in the real space. Further exploration of these phases can shed light on the mechanism of unconventional superconductivity. Here we report on the discovery of a peculiar spatially-varying superconducting state residing at the interface between (110)-oriented KTaO3 and ferromagnetic EuO. Electrical transport measurements reveal different Tc and upper critical fields (Hc2) with current applied along the two orthogonal in-plane directions. Such anisotropy persistently occurs in the low-carrier-density samples that are characterized by strong coupling between Ta 5d and Eu 4f electrons, whereas in the high-carrier-density samples the coupling is weakened and Tc and Hc2 becomes isotropic. Complemented by local imaging of diamagnetism and theoretical analysis, our observations imply an unprecedented emergence of superconducting stripes wherein the phase coherence is established ahead of the rest of the interface, arising from a band-filling-dependent ferromagnetic proximity. The realization of such exotic superconducting states provides impetus for the study of novel physics in heterostructures possessing both magnetism and superconductivity.