Quasiparticle effects in magnetic-field-resilient three-dimensional transmons

Recent research shows that quasiparticle-induced decoherence of superconducting qubits depends on the superconducting-gap asymmetry originating from the different thicknesses of the top and bottom films in $\mathrm{Al}$/${\mathrm{Al}\mathrm{O}}_{x}$/$\mathrm{Al}$ junctions. Magnetic field is a key tuning knob to investigate this dependence as it can change the superconducting gaps in situ. We present measurements of the parity-switching time of a field-resilient three-dimensional transmon with in-plane field up to 0.41 T. At low fields, small parity splitting requires qutrit pulse sequences for parity measurements. We measure a nonmonotonic evolution of the parity lifetime with in-plane magnetic field, increasing up to 0.2 T, followed by a decrease at higher fields. We demonstrate that the superconducting-gap asymmetry plays a crucial role in the observed behavior. At zero field, the qubit frequency is nearly resonant with the superconducting-gap difference, favoring the energy exchange with the quasiparticles and so enhancing the parity-switching rate. With a higher magnetic field, the qubit frequency decreases and gets detuned from the gap difference, causing the initial increase of the parity lifetime, while photon-assisted qubit transitions increase, producing the subsequent decrease at higher fields. Besides giving a deeper insight into the parity-switching mechanism in conventional transmon qubits, we establish that $\mathrm{Al}$-${\mathrm{Al}\mathrm{O}}_{x}$-$\mathrm{Al}$ Josephson junctions could be used in architectures for the parity-readout and manipulation of topological qubits based on Majorana zero modes.