Low-frequency spin qubit detuning noise in highly purified 28Si/SiGe

Abstract

The manipulation fidelity of a single electron qubit gate-confined in a 28Si/SiGe quantum dot has recently been drastically improved by nuclear isotope purification. Here, we identify the dominant source for low-frequency qubit detuning noise in a device with an embedded nanomagnet, a remaining 29Si concentration of only 60\,ppm in the strained 28Si quantum well layer and a spin echo decay time T2echo=128\,μs. The power spectral density (PSD) of the charge noise explains both the observed transition of a 1/f2- to a 1/f-dependence of the detuning noise PSD as well as the observation of a decreasing time-ensemble spin dephasing time from T2* ≈ 20\,μs with increasing measurement time over several hours. Despite their strong hyperfine contact interaction, the few 73Ge nuclei overlapping with the quantum dot in the barrier do not limit T2*, as their dynamics is frozen on a few hours measurement scale. We conclude that charge noise and the design of the gradient magnetic field is the key to further improve the qubit fidelity.