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Realizing tight-binding Hamiltonians using site-controlled coupled cavity arrays

Author

Listed:
  • Abhi Saxena

    (University of Washington)

  • Arnab Manna

    (University of Washington)

  • Rahul Trivedi

    (University of Washington)

  • Arka Majumdar

    (University of Washington
    University of Washington)

Abstract

Analog quantum simulators rely on programmable and scalable quantum devices to emulate Hamiltonians describing various physical phenomenon. Photonic coupled cavity arrays are a promising alternative platform for realizing such simulators, due to their potential for scalability, small size, and high-temperature operability. However, programmability and nonlinearity in photonic cavities remain outstanding challenges. Here, using a silicon photonic coupled cavity array made up of $$8$$ 8 high quality factor ( $$Q$$ Q up to $$\, \sim 7.1\times {10}^{4}$$ ~ 7.1 × 10 4 ) resonators and equipped with specially designed thermo-optic island heaters for independent control of cavities, we demonstrate a programmable photonic cavity array in the telecom regime, implementing tight-binding Hamiltonians with access to the full eigenenergy spectrum. We report a $$\sim 50\%$$ ~ 50 % reduction in the thermal crosstalk between neighboring sites of the cavity array compared to traditional heaters, and then present a control scheme to program the cavity array to a given tight-binding Hamiltonian. The ability to independently program high-Q photonic cavities, along with the compatibility of silicon photonics to high volume manufacturing opens new opportunities for scalable quantum simulation using telecom regime infrared photons.

Suggested Citation

  • Abhi Saxena & Arnab Manna & Rahul Trivedi & Arka Majumdar, 2023. "Realizing tight-binding Hamiltonians using site-controlled coupled cavity arrays," Nature Communications, Nature, vol. 14(1), pages 1-7, December.
  • Handle: RePEc:nat:natcom:v:14:y:2023:i:1:d:10.1038_s41467-023-41034-x
    DOI: 10.1038/s41467-023-41034-x
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    References listed on IDEAS

    as
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    2. Ruichao Ma & Brendan Saxberg & Clai Owens & Nelson Leung & Yao Lu & Jonathan Simon & David I. Schuster, 2019. "A dissipatively stabilized Mott insulator of photons," Nature, Nature, vol. 566(7742), pages 51-57, February.
    3. Stefan Krastanov & Mikkel Heuck & Jeffrey H. Shapiro & Prineha Narang & Dirk R. Englund & Kurt Jacobs, 2021. "Room-temperature photonic logical qubits via second-order nonlinearities," Nature Communications, Nature, vol. 12(1), pages 1-10, December.
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