TY - GEN

T1 - Scalable Quantum Signal Processing with Integrated Photonics and Fiber-based Modules

AU - Montaut, Nicola

AU - Roztocki, Piotr

AU - Yu, Hao

AU - Sciara, Stefania

AU - Chemnitz, Mario

AU - Jestin, Yoann

AU - Maclellan, Benjamin

AU - Fischer, Bennet

AU - Kues, Michael

AU - Reimer, Christian

AU - Cortes, Luis Romero

AU - Wetzel, Benjamin

AU - Zhang, Yanbing

AU - Loranger, Sebastien

AU - Kashyap, Raman

AU - Cino, Alfonso

AU - Chu, Sai T.

AU - Little, Brent E.

AU - Moss, David J.

AU - Caspani, Lucia

AU - Munro, William J.

AU - Azaña, José

AU - Morandotti, Roberto

PY - 2023

Y1 - 2023

N2 - Quantum photonic resources are critical for advanced applications such as quantum computation, communication, and information processing. Efficient generation and detection of quantum states, as well as reliable photon manipulation techniques, are essential for the development of practical quantum technologies. Integrated photonic platforms offer attractive solutions due to their stability, small device footprint, and improved power efficiencies. However, optical loss and environmental noise hinder their capability to transmit, measure, and detect quantum states with high accuracies. To tackle these limitations, we have developed robust solutions for quantum signal processing by leveraging infrastructures from telecommunications and integrated photonics. These approaches focus on the use of silicon-based photonic sources for entanglement generation in the time and frequency degrees of freedom, as well as chip- and fiber-based architectures for entanglement verification via quantum interference and tomography measurements. Our photonic schemes allow for high-dimensional entanglement processing, demonstrating their versatility in developing scalable and cost-efficient quantum signal processing platforms.

AB - Quantum photonic resources are critical for advanced applications such as quantum computation, communication, and information processing. Efficient generation and detection of quantum states, as well as reliable photon manipulation techniques, are essential for the development of practical quantum technologies. Integrated photonic platforms offer attractive solutions due to their stability, small device footprint, and improved power efficiencies. However, optical loss and environmental noise hinder their capability to transmit, measure, and detect quantum states with high accuracies. To tackle these limitations, we have developed robust solutions for quantum signal processing by leveraging infrastructures from telecommunications and integrated photonics. These approaches focus on the use of silicon-based photonic sources for entanglement generation in the time and frequency degrees of freedom, as well as chip- and fiber-based architectures for entanglement verification via quantum interference and tomography measurements. Our photonic schemes allow for high-dimensional entanglement processing, demonstrating their versatility in developing scalable and cost-efficient quantum signal processing platforms.

KW - entangled photons

KW - fiber-based optical modules

KW - integrated quantum photonics

KW - microring resonators

KW - on-chip interferometers

KW - quantum signal processing

UR - http://www.scopus.com/inward/record.url?scp=85169417186&partnerID=8YFLogxK

U2 - 10.1109/ICTON59386.2023.10207524

DO - 10.1109/ICTON59386.2023.10207524

M3 - Conference contribution

AN - SCOPUS:85169417186

SN - 979-8-3503-0304-9

T3 - International Conference on Transparent Optical Networks

BT - 2023 23rd International Conference on Transparent Optical Networks

A2 - Jaworski, Marek

A2 - Marciniak, Marian

PB - IEEE Computer Society

T2 - 23rd International Conference on Transparent Optical Networks, ICTON 2023

Y2 - 2 July 2023 through 6 July 2023

ER -