Monolithically Integrated C-Band Quantum Emitters on Foundry Silicon Photonics
- URL: http://arxiv.org/abs/2505.00224v1
- Date: Thu, 01 May 2025 00:11:40 GMT
- Title: Monolithically Integrated C-Band Quantum Emitters on Foundry Silicon Photonics
- Authors: Robert M. Pettit, Skylar Deckoff-Jones, Angela Donis, Ana Elias, Jayson Briscoe, Gerald Leake, Daniel Coleman, Michael Fanto, Ananthesh Sundaresh, Shobhit Gupta, Manish Kumar Singh, Sean E. Sullivan,
- Abstract summary: Photonic crystal cavities are often used to enhance radiative emission.<n> fabrication of the necessary subwavelength cavities is typically limited to small batch electron beam lithography.<n>In this work, we demonstrate high quality factor, small mode volume nanobeam cavities fabricated on a scalable silicon photonic foundry platform.
- Score: 0.1274993005219167
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Solid-state spin-based quantum systems have emerged as popular platforms for quantum networking applications due to their optical interfaces, their long-lived quantum memories, and their natural compatibility with semiconductor manufacturing. Photonic crystal cavities are often used to enhance radiative emission; however, fabrication of the necessary subwavelength cavities is typically limited to small batch electron beam lithography. In this work, we demonstrate high quality factor, small mode volume nanobeam cavities fabricated on a scalable silicon photonic foundry platform. The foundry fabricated cavities are then interfaced with single erbium ions through backend deposition of TiO2 thin films lightly doped with erbium. Single ion lifetime measurements indicate Purcell enhancement up to about 500, thereby demonstrating a route toward manufacturable deterministic single photon sources in the telecom C-band.
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