Switchable geometric frustration in an artificial-spin-ice-superconductor hetero-system

TL;DR

This paper demonstrates in-situ controllable geometric frustration with massive degeneracy in a 2D flux quantum system by integrating a reconfigurable artificial-spin-ice structure with a superconducting film, enabling reprogrammable functionalities.

Contribution

It introduces a novel method to achieve tunable geometric frustration in a 2D superconductor using artificial-spin-ice, allowing dynamic control over flux states and potential applications in reprogrammable devices.

Findings

Achieved controllable switching between frustrated and ordered flux states.

Demonstrated a reprogrammable flux quanta diode.

Showed measurable effects on superconducting critical current profiles.

Abstract

Geometric frustration emerges when local interaction energies in an ordered lattice structure cannot be simultaneously minimized, resulting in a large number of degenerate states. The numerous degenerate configurations may lead to practical applications in microelectronics, such as data storage, memory and logic. However, it is difficult to achieve extensive degeneracy, especially in a two-dimensional system. Here, we showcase in-situ controllable geometric frustration with massive degeneracy in a two-dimensional flux quantum system. We create this in a superconducting thin film placed underneath a reconfigurable artificial-spin-ice structure. The tunable magnetic charges in the artificial-spin-ice strongly interact with the flux quanta in the superconductor, enabling the switching between frustrated and crystallized flux quanta states. The different states have measurable effects on the superconducting critical current profile, which can be reconfigured by precise selection of the spin ice magnetic state through application of an external magnetic field. We demonstrate the applicability of these effects by realizing a reprogrammable flux quanta diode. The tailoring of the energy landscape of interacting 'particles' using artificial-spin-ices provides a new paradigm for the design of geometric frustration, which allows us to control new functionalities in other material systems, such as magnetic skyrmions, electrons/holes in two-dimensional materials and topological insulators, as well as colloids in soft materials.