Experimental realization of a (2) transmon qubit

Abstract

Superconducting circuits with embedded symmetries are good candidates to robustly protect quantum information from dominant error channels. The (2) qubit, consisting of an island shunted to ground through a tunneling element that selectively transmits pairs of Cooper pairs, leverages charge-parity symmetry to protect from charge-induced errors. In this experiment, we observe a doublet of states of opposite Cooper-pair parity split by 13.6~MHz. Operating in a soft-transmon regime, this splitting is two orders of magnitude smaller than in previous implementations, pushing charge-induced losses well beyond the measured coherence times. Despite the low transition frequency, we demonstrate coherent qubit control, single-shot readout, and resolve quantum jumps. Charge protection of the qubit is evidenced by a 100-fold suppression of the island charge matrix element compared to the unprotected plasmon transition, placing dielectric loss limits above 10~ms. The measured T1 = 70~μs and T2echo= 2.5~μs are instead limited by 1/f flux noise in the tunnelling element's loop. This experiment shows that pushing Cooper-pair pairing in the transmon regime sets high limits on charge-induced losses while preserving coherent control and single-shot readout of the low-frequency qubit. We identify flux noise as the dominant remaining limitation, calling for gradiometric designs or novel 4e-tunneling elements.

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