Spin-augmented observables for efficient photonic quantum error correction

TL;DR

This paper proposes a novel method for quantum error correction using spin states of solid-state emitters as measure qubits, enabling efficient syndrome measurements via photon-spin interactions in microcavities.

Contribution

It introduces a spin-augmented observable protocol for photonic quantum error correction that is adaptable to various resource constraints and tolerant to system imperfections.

Findings

Spin states can serve as measure qubits for syndrome extraction.

Photon-spin interactions enable quantum non-demolition measurements.

High-fidelity entanglement achievable despite energy mismatches.

Abstract

We demonstrate that the spin state of solid-state emitters inside micropillar cavities can serve as measure qubits in syndrome measurements. The photons, acting as data qubits, interact with the spin state in the microcavity and the total state of the system evolves conditionally due to the resulting circular birefringence. By performing a quantum non-demolition measurement on the spin state, the syndrome of the optical state can be obtained. Furthermore, due to the symmetry of the interaction, we can alternatively choose to employ the optical states as measure qubits. This protocol can be adapted to various resource requirements, including spectral discrepancies between the data qubits and codes with modified connectivities, by considering entangled measure qubits. Finally, we show that spin-systems with dissimilar characteristic energies can still be entangled with high levels of fidelity and tolerance to cavity losses in the strong coupling regime.