Generalized scaling of spin qubit coherence in over 12,000 host materials.
Shun KanaiF Joseph HeremansHosung SeoGary WolfowiczChristopher P AndersonSean E SullivanMykyta OnizhukGiulia GalliDavid D AwschalomHideo OhnoPublished in: Proceedings of the National Academy of Sciences of the United States of America (2022)
SignificanceAtomic defects in solid-state materials are promising candidates as quantum bits, or qubits. New materials are actively being investigated as hosts for new defect qubits; however, there are no unifying guidelines that can quantitatively predict qubit performance in a new material. One of the most critical property of qubits is their quantum coherence. While cluster correlation expansion (CCE) techniques are useful to simulate the coherence of electron spins in defects, they are computationally expensive to investigate broad classes of stable materials. Using CCE simulations, we reveal a general scaling relation between the electron spin coherence time and the properties of qubit host materials that enables rapid and quantitative exploration of new materials hosting spin defects.