Abstract
Photonic integrated circuits (PICs) are expected to play a significant role in the ongoing second quantum revolution, thanks to their stability and scalability. Still, major upgrades are needed for available PIC platforms to meet the demanding requirements of quantum devices. We present a review of our recent progress in upgrading an unconventional silicon photonics platform toward this goal, including ultralow propagation losses, low-fiber coupling losses, integration of superconducting elements, Faraday rotators, fast and efficient detectors, and phase modulators with low-loss and/or low-energy consumption. We show the relevance of our developments and our vision in the main applications of quantum key distribution, to achieve significantly higher key rates and large-scale deployment; and cryogenic quantum computers, to replace electrical connections to the cryostat with optical fibers.
| Original language | English |
|---|---|
| Article number | 024002 |
| Journal | Advanced Photonics Nexus |
| Volume | 2 |
| Issue number | 2 |
| DOIs | |
| Publication status | Published - 6 Apr 2023 |
| MoE publication type | A2 Review article in a scientific journal |
Funding
This work was supported by the European Union’s Horizon 2020 Research and Innovation Program through projects aCryComm (Grant No. 899558), Quantum e-leaps (Grant No. 862660), OpenSuperQ (Grant No. 820363), EFINED (Grant No. 766853), and EMPIR SuperQuant (Project No. 20FUN07). We would like to acknowledge the support by the Academy of Finland Flagship Program, Photonics Research and Innovation (PREIN) (Decision No. 320168) and VTT Internal Quantum Initiative “Quantum leap in quantum control.” This work was performed as part of the Academy of Finland Centre of Excellence program (Project No. 336817) and projects ETHEC (Grant No. 322580) and QuantLearn (Grant No. 350220). We also would like to acknowledge financial support from Business Finland through projects QuTI (No. 40562/31/2020) and PICAP (No. 44065/31/2020).
Keywords
- cryogenic photonics
- quantum computers
- quantum key distribution
- quantum technologies
- silicon photonics
- silicon qubits
- superconducting nanowire single-photon detectors
- superconducting qubits
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Dive into the research topics of 'Supporting quantum technologies with an ultralow-loss silicon photonics platform'. Together they form a unique fingerprint.Projects
- 4 Finished
-
QuantLearn: Diverse computing ecosystem for quantum machine learning via optical links
Kemppinen, A. (Manager), Cherchi, M. (Participant), Tappura, K. (Participant), Vesterinen, V. (Participant) & Nissilä, J. (Participant)
1/01/22 → 31/12/24
Project: Research Council of Finland
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SuperQuant: Microwave metrology for superconducting quantum circuits
Manninen, A. (Manager), Nissilä, J. (Participant) & Nyholm, K. (Participant)
1/06/21 → 31/05/24
Project: EU project
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aCryComm: attojoule Cryogenic Communication
Cherchi, M. (Manager), Govenius, J. (Participant), Mykkänen, E. (Participant), Pursula, P. (Owner), Kemppinen, A. (Participant), Tappura, K. (Participant), Delrosso, G. (Participant), Grönberg, L. (Participant), Lehtimäki, L. (Participant), Bera, A. (Participant), Prunnila, M. (Participant), Kiviranta, M. (Participant) & Kohopää, K. (Participant)
1/10/20 → 29/09/23
Project: EU project
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