Quasiparticles in Superconducting Qubits with Asymmetric Junctions

Designing the spatial profile of the superconducting gap-gap engineering-has long been recognized as an effective way of controlling quasiparticles in superconducting devices. In aluminum films, their thickness modulates the gap; therefore, standard fabrication of Al/AlOx/Al Josephson junctions, which relies on overlapping a thicker film on top of a thinner one, always results in gap-engineered devices. Here, we reconsider quasiparticle effects in superconducting qubits to explicitly account for the unavoidable asymmetry in the gap on the two sides of a Josephson junction. We find that different regimes can be encountered in which the quasiparticles have either similar densities in the two junction leads or are largely confined to the lower-gap lead. Qualitatively, for similar densities the qubit excited-state population is lower but its relaxation rate is higher than when the quasiparticles are confined; therefore, there is a potential trade-off between two desirable properties in a qubit.

Automated summary

Designing the spatial profile of the superconducting gap, known as gap engineering, is an effective way to control quasiparticles in superconducting devices. In this study, the quasiparticle effects in superconducting qubits are reconsidered to account for the inevitable asymmetry in the gap on the two sides of a Josephson junction. Different regimes are found, where quasiparticles have either similar densities in the two junction leads or are largely confined to one side with lower gap. The qubit's excited-state population is lower but its relaxation rate is higher when the quasiparticles are confined, indicating a potential trade-off between two desirable properties in a qubit.