Charge-induced energy shift of a single-spin qubit under a magnetic-field gradient

TL;DR

This study investigates how charge configurations in neighboring quantum dots cause energy shifts in a silicon single-spin qubit within a magnetic-field gradient, highlighting the need for precise electron position control for high-fidelity quantum operations.

Contribution

It provides spectroscopic evidence of charge-induced energy shifts in a single-spin qubit and demonstrates the correlation between charge states and qubit frequency in a magnetic gradient.

Findings

Charge configuration changes induce ~4 MHz energy shifts.

A correlation exists between charge states and qubit frequency.

Electron position management is crucial for qubit fidelity.

Abstract

An electron confined by a semiconductor quantum dot (QD) can be displaced by changes in electron occupations of surrounding QDs owing to the Coulomb interaction. For a single-spin qubit in an inhomogeneous magnetic field, such a displacement of the host electron results in a qubit energy shift which must be handled carefully for high-fidelity operations. Here we spectroscopically investigate the qubit energy shift induced by changes in charge occupations of nearby QDs for a silicon single-spin qubit in a magnetic-field gradient. Between two different charge configurations of an adjacent double QD, a spin qubit shows an energy shift of about 4 MHz, which necessitates strict management of electron positions over a QD array. We confirm a correlation between the qubit frequency and the charge configuration by using a postselection analysis.