Improving the Lifetime of Aluminum-Based Superconducting Qubits through Atomic Layer Etching and Deposition

We present a dry surface treatment combining atomic layer etching and deposition (ALE and ALD) to mitigate dielectric loss in fully fabricated superconducting quantum devices formed from aluminum thin films on silicon. The treatment, performed as a final processing step prior to device packaging, starts by conformally removing the native metal oxide and fabrication residues from the exposed surfaces through ALE, before in situ encapsulating the metal surfaces with a thin dielectric layer using ALD. We measure a 2-fold reduction in loss attributed to two-level system (TLS) absorption in treated aluminum-based resonators and planar transmon qubits. Treated transmons with compact capacitor plates and gaps achieve median transmon quality factor (Q) and transmon qubit energy relaxation time (T1) values of 3.69 ± 0.42 × 106 and 196 ± 22 μs, respectively. These improvements were found to be sustained over several months. We discuss how the combination of ALE and ALD reverses fabrication-induced surface damage to significantly and durably improve device performance via a reduction of the TLS defect density in the capacitive elements.