Precision high-speed quantum logic with holes on a natural silicon foundry platform

Available on arXiv

Isaac Vorreiter, Jonathan Y Huang, Scott D Liles, Joe Hillier, Ruoyu Li, Bart Raes, Stefan Kubicek, Julien Jussot, Sofie Beyne, Clement Godfrin, Sugandha Sharma, Danny Wan, Nard Dumoulin Stuyck, Will Gilbert, Chih Hwan Yang, Andrew S Dzurak, Kristiaan De Greve, Alexander R Hamilton

Abstract

Silicon spin qubits in gate-defined quantum dots leverage established semiconductor infrastructure and offer a scalable path toward transformative quantum technologies. Holes spins in silicon offer compact all-electrical control, whilst retaining all the salient features of a quantum dot qubit architecture. However, silicon hole spin qubits are not as advanced as electrons, due to increased susceptibility to disorder and more complex spin physics. Here we demonstrate single-qubit gate fidelities up to 99.8% and a two-qubit gate quality factor of 240, indicating a physical fidelity limit of 99.7%. These results represent the highest performance reported in natural silicon to date, made possible by fast qubit control, exchange pulsing, and industrial-grade fabrication. Notably, we achieve these results in a near-identical device as used for highly reproducible, high-fidelity electron spin qubits. With isotopic purification and device-level optimisations in the future, our hole spin qubits are poised to unlock a new operation regime for quantum CMOS architectures.