Quantum Artificial Spin Ice

Artificial spin ice systems have heralded a new paradigm in which frustrated systems are deliberately manufactured via fine tuning of geometry and topology to design and characterize exotic, emergent phenomena at the constituent level with unprecedented control. Here we report the first realization of artificial spin ice in a lattice of coupled superconducting flux qubits. Unlike previous, classical realizations of artificial spin ice, our system is disordered by both thermal and quantum fluctuations, while its ground state is still classically described by the ice rule and the desired low-energy correlations of a Coulomb phase balanced at a fragile degeneracy point. Exploiting the reconfigurability of our new realization, we demonstrate for the first time Gauss' law for emergent effective monopoles in two dimensions, as well as purely entropic monopole-monopole screening and interaction. We explore its quasi-classical kinetics, driven primarily by quantum rather than thermal fluctuations, and reveal the role of monopole excitations as catalysts for rapid mixing. These experiments lay the groundwork for potential future study of reconfigurable, artificial quantum spin liquids.