Direct visualization of vortex ice in a nanostructured superconductor

TL;DR

This paper presents the first direct imaging of vortex ice states in a nanostructured superconductor, confirming theoretical predictions and revealing defect types and controllability via magnetic field variations.

Contribution

It provides the first direct visualization of vortex ice configurations in a superconductor, advancing understanding of artificial ice systems and defect control.

Findings

Vortex ice ground state confirmed via scanning Hall probe microscopy.

Different defect types visualized and identified.

Defect types can be controlled by varying magnetic field.

Abstract

Artificial ice systems have unique physical properties promising for potential applications. One of the most challenging issues in this field is to find novel ice systems that allows a precise control over the geometries and many-body interactions. Superconducting vortex matter has been proposed as a very suitable candidate to study artificial ice, mainly due to availability of tunable vortex-vortex interactions and the possibility to fabricate a variety of nanoscale pinning potential geometries. So far, a detailed imaging of the local configurations in a vortex-based artificial ice system is still lacking. Here we present a direct visualization of the vortex ice state in a nanostructured superconductor. By using the scanning Hall probe microscopy, a large area with the vortex ice ground state configuration has been detected, which confirms the recent theoretical predictions for this new ice system. Besides the defects analogous to artificial spin ice systems, other types of defects have been visualized and identified. We also demonstrate the possibility to realize different types of defects by varying the magnetic field.