We present a programmable silicon photonic four-qubit integrated circuit for the generation and manipulation of diverse quantum states. The silicon photonic chip integrates photon-pair sources, pump-reducing filters, wavelength-division-multiplexing filters, Mach-Zehnder interferometer switches, and single-qubit arbitrary gates, enabling versatile state preparation and tomography. We measure Hong-Ou-Mandel interference with an impressive 98% visibility using four-photon coincidence, laying the foundation for high-purity qubits. Our analysis involves estimating the fidelity and purity of distinct quantum states through maximum-likelihood estimation applied to tomographic measurements. In our experimental results, we showcase the following achievements: a heralded single qubit achieving 98.2% fidelity and 98.3% purity, a Bell state reaching 95.2% fidelity and 94.8% purity, and a four-qubit system with two simultaneous Bell states exhibiting 87.4% fidelity and 84.6% purity. Finally, a four-qubit Greenberger-Horne-Zeilinger (GHZ) state demonstrates 85.4% fidelity and 81.7% purity. In addition, we certify the entanglement of the four-photon GHZ state through Bell’s inequality violations and a negative entanglement witness.

Quantum states generation and manipulation in a programmable silicon-photonic four-qubit system with high-fidelity and purity / Lee, J. -M.; Park, J.; Bang, J.; Sohn, Y. -I.; Baldazzi, A.; Sanna, M.; Azzini, S.; Pavesi, L.. - In: APL PHOTONICS. - ISSN 2378-0967. - 9:7(2024). [10.1063/5.0207714]

Quantum states generation and manipulation in a programmable silicon-photonic four-qubit system with high-fidelity and purity

Baldazzi A.;Sanna M.;Azzini S.;Pavesi L.
2024-01-01

Abstract

We present a programmable silicon photonic four-qubit integrated circuit for the generation and manipulation of diverse quantum states. The silicon photonic chip integrates photon-pair sources, pump-reducing filters, wavelength-division-multiplexing filters, Mach-Zehnder interferometer switches, and single-qubit arbitrary gates, enabling versatile state preparation and tomography. We measure Hong-Ou-Mandel interference with an impressive 98% visibility using four-photon coincidence, laying the foundation for high-purity qubits. Our analysis involves estimating the fidelity and purity of distinct quantum states through maximum-likelihood estimation applied to tomographic measurements. In our experimental results, we showcase the following achievements: a heralded single qubit achieving 98.2% fidelity and 98.3% purity, a Bell state reaching 95.2% fidelity and 94.8% purity, and a four-qubit system with two simultaneous Bell states exhibiting 87.4% fidelity and 84.6% purity. Finally, a four-qubit Greenberger-Horne-Zeilinger (GHZ) state demonstrates 85.4% fidelity and 81.7% purity. In addition, we certify the entanglement of the four-photon GHZ state through Bell’s inequality violations and a negative entanglement witness.
2024
7
Lee, J. -M.; Park, J.; Bang, J.; Sohn, Y. -I.; Baldazzi, A.; Sanna, M.; Azzini, S.; Pavesi, L.
Quantum states generation and manipulation in a programmable silicon-photonic four-qubit system with high-fidelity and purity / Lee, J. -M.; Park, J.; Bang, J.; Sohn, Y. -I.; Baldazzi, A.; Sanna, M.; Azzini, S.; Pavesi, L.. - In: APL PHOTONICS. - ISSN 2378-0967. - 9:7(2024). [10.1063/5.0207714]
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11572/432338
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