Physical Review X (Aug 2019)

Quantum Interference of Electromechanically Stabilized Emitters in Nanophotonic Devices

  • B. Machielse,
  • S. Bogdanovic,
  • S. Meesala,
  • S. Gauthier,
  • M. J. Burek,
  • G. Joe,
  • M. Chalupnik,
  • Y. I. Sohn,
  • J. Holzgrafe,
  • R. E. Evans,
  • C. Chia,
  • H. Atikian,
  • M. K. Bhaskar,
  • D. D. Sukachev,
  • L. Shao,
  • S. Maity,
  • M. D. Lukin,
  • M. Lončar

DOI
https://doi.org/10.1103/PhysRevX.9.031022
Journal volume & issue
Vol. 9, no. 3
p. 031022

Abstract

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Photon-mediated coupling between distant matter qubits may enable secure communication over long distances, the implementation of distributed quantum computing schemes, and the exploration of new regimes of many-body quantum dynamics. Solid-state quantum emitters coupled to nanophotonic devices represent a promising approach towards these goals, as they combine strong light-matter interaction and high photon collection efficiencies. However, nanostructured environments introduce mismatch and diffusion in optical transition frequencies of emitters, making reliable photon-mediated entanglement generation infeasible. Here we address this long-standing challenge by employing silicon-vacancy color centers embedded in electromechanically deflectable nanophotonic waveguides. This electromechanical strain control enables control and stabilization of optical resonance between two silicon-vacancy centers on the hour timescale. Using this platform, we observe the signature of an entangled, superradiant state arising from quantum interference between two spatially separated emitters in a waveguide. This demonstration and the developed platform constitute a crucial step towards a scalable quantum network with solid-state quantum emitters.