Modular chip-integrated photonic control of artificial atoms in diamond waveguides
Author
Palm, K.J.Dong, M.
Golter, D.A.
Clark, G.
Zimmermann, M.
Chen, K.C.
Li, L.
Menssen, A.
Leenheer, A.J.
Dominguez, D.
Gilbert, G.
Eichenfield, M.
Englund, D.
Affiliation
Wyant College of Optical Sciences, University of ArizonaIssue Date
2023-05-18
Metadata
Show full item recordPublisher
Optica Publishing Group (formerly OSA)Citation
Kevin J. Palm, Mark Dong, D. Andrew Golter, Genevieve Clark, Matthew Zimmermann, Kevin C. Chen, Linsen Li, Adrian Menssen, Andrew J. Leenheer, Daniel Dominguez, Gerald Gilbert, Matt Eichenfield, and Dirk Englund, "Modular chip-integrated photonic control of artificial atoms in diamond waveguides," Optica 10, 634-641 (2023)Journal
OpticaRights
© 2023 Optica Publishing Group under the terms of the Optica Open Access Publishing Agreement.Collection Information
This item from the UA Faculty Publications collection is made available by the University of Arizona with support from the University of Arizona Libraries. If you have questions, please contact us at repository@u.library.arizona.edu.Abstract
A central goal in creating long-distance quantum networks and distributed quantum computing is the development of interconnected and individually controlled qubit nodes. Atom-like emitters in diamond have emerged as a leading system for optically networked quantum memories, motivating the development of visible-spectrum, multi-channel photonic integrated circuit (PIC) systems for scalable atom control. However, it has remained an open challenge to realize optical programmability with a qubit layer that can achieve high optical detection probability over many optical channels. Here, we address this problem by introducing a modular architecture of piezoelectrically actuated atom-control PICs (APICs) and artificial atoms embedded in diamond nanostructures designed for high-efficiency free-space collection. The high-speed four-channel APIC is based on a splitting tree mesh with triple-phase shifter Mach–Zehnder interferometers. This design simultaneously achieves optically broadband operation at visible wavelengths, high-fidelity switching (>40 dB) at low voltages, submicrosecond modulation timescales (>30 MHz), and minimal channel-to-channel crosstalk for repeatable optical pulse carving. Via a reconfigurable free-space interconnect, we use the APIC to address single silicon vacancy color centers in individual diamond waveguides with inverse tapered couplers, achieving efficient single photon detection probabilities (∼15%) and second-order autocorrelation measurements g (2)(0) < 0.14 for all channels. The modularity of this distributed APIC–quantum memory system simplifies the quantum control problem, potentially enabling further scaling to thousands of channels. © 2023 Optica Publishing Group under the terms of the Optica Open Access Publishing Agreement.Note
Immediate accessISSN
2334-2536Version
Final Published Versionae974a485f413a2113503eed53cd6c53
10.1364/OPTICA.486361