Grover's Algorithm in a Four-qubit Silicon Processor Above the Fault-tolerant Threshold

Overview

Journal Nat Nanotechnol

Specialty Biotechnology

Date 2025 Feb 20

PMID 39979400

Authors

I Thorvaldson

D Poulos

C M Moehle

S H Misha

H Edlbauer

J Reiner

H Geng

B Voisin

M T Jones

M B Donnelly

L F Pena

C D Hill

C R Myers

J G Keizer

Y Chung

S K Gorman

L Kranz

M Y Simmons

Affiliations

Soon will be listed here.

Abstract

Spin qubits in silicon are strong contenders for the realization of a practical quantum computer, having demonstrated single- and two-qubit gates with fidelities above the fault-tolerant threshold, and entanglement of three qubits. However, maintaining high-fidelity operations while increasing the qubit count remains challenging and therefore only two-qubit algorithms have been executed. Here we utilize a four-qubit silicon processor with all control fidelities above the fault-tolerant threshold and demonstrate a three-qubit Grover's search algorithm with a ~95% probability of finding the marked state. Our processor is made of three phosphorus atoms precision-patterned into isotopically pure silicon, which localise one electron. The long coherence times of the qubits enable single-qubit fidelities above 99.9% for all qubits. Moreover, the efficient single-pulse multi-qubit operations enabled by the electron-nuclear hyperfine interaction facilitate controlled-Z gates between all pairs of nuclear spins with fidelities above 99% when using the electron as an ancilla. These control fidelities, combined with high-fidelity non-demolition readout of all nuclear spins, allow the creation of a three-qubit Greenberger-Horne-Zeilinger state with 96.2% fidelity. Looking ahead, coupling neighbouring nuclear spin registers, as the one shown here, via electron-electron exchange may enable larger, fault-tolerant quantum processors.

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