Bell's inequality violation with spins in silicon

TL;DR

This paper demonstrates the deterministic generation and high-fidelity measurement of entangled electron and nuclear spins in a silicon-based quantum device, violating Bell's inequality and showcasing advanced quantum control.

Contribution

It presents the first on-demand entangled state generation in silicon with Bell inequality violation and high-fidelity quantum non-demolition measurements.

Findings

Bell signal of 2.50(10) demonstrating violation

Bell signal of 2.70(9) with QND measurement

>96% fidelity in state preparation and tomography

Abstract

Bell's theorem sets a boundary between the classical and quantum realms, by providing a strict proof of the existence of entangled quantum states with no classical counterpart. An experimental violation of Bell's inequality demands simultaneously high fidelities in the preparation, manipulation and measurement of multipartite quantum entangled states. For this reason the Bell signal has been tagged as a single-number benchmark for the performance of quantum computing devices. Here we demonstrate deterministic, on-demand generation of two-qubit entangled states of the electron and the nuclear spin of a single phosphorus atom embedded in a silicon nanoelectronic device. By sequentially reading the electron and the nucleus, we show that these entangled states violate the Bell/CHSH inequality with a Bell signal of 2.50(10). An even higher value of 2.70(9) is obtained by mapping the parity of the two-qubit state onto the nuclear spin, which allows for high-fidelity quantum non-demolition measurement (QND) of the parity. Furthermore, we complement the Bell inequality entanglement witness with full two-qubit state tomography exploiting QND measurement, which reveals that our prepared states match the target maximally entangled Bell states with $>$96\% fidelity. These experiments demonstrate complete control of the two-qubit Hilbert space of a phosphorus atom, and show that this system is able to maintain its simultaneously high initialization, manipulation and measurement fidelities past the single-qubit regime.