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Quantum control of surface acoustic-wave phonons

Author

Listed:
  • K. J. Satzinger

    (University of California
    University of Chicago)

  • Y. P. Zhong

    (University of Chicago)

  • H.-S. Chang

    (University of Chicago)

  • G. A. Peairs

    (University of California
    University of Chicago)

  • A. Bienfait

    (University of Chicago)

  • Ming-Han Chou

    (University of Chicago
    University of Chicago)

  • A. Y. Cleland

    (University of Chicago)

  • C. R. Conner

    (University of Chicago)

  • É. Dumur

    (University of Chicago
    Argonne National Laboratory, Argonne)

  • J. Grebel

    (University of Chicago)

  • I. Gutierrez

    (University of Chicago)

  • B. H. November

    (University of Chicago)

  • R. G. Povey

    (University of Chicago
    University of Chicago)

  • S. J. Whiteley

    (University of Chicago
    University of Chicago)

  • D. D. Awschalom

    (University of Chicago
    Argonne National Laboratory, Argonne)

  • D. I. Schuster

    (University of Chicago)

  • A. N. Cleland

    (University of Chicago
    Argonne National Laboratory, Argonne)

Abstract

One of the hallmarks of quantum physics is the generation of non-classical quantum states and superpositions, which has been demonstrated in several quantum systems, including ions, solid-state qubits and photons. However, only indirect demonstrations of non-classical states have been achieved in mechanical systems, despite the scientific appeal and technical utility of such a capability1,2, including in quantum sensing, computation and communication applications. This is due in part to the highly linear response of most mechanical systems, which makes quantum operations difficult, as well as their characteristically low frequencies, which hinder access to the quantum ground state3–7. Here we demonstrate full quantum control of the mechanical state of a macroscale mechanical resonator. We strongly couple a surface acoustic-wave8 resonator to a superconducting qubit, using the qubit to control and measure quantum states in the mechanical resonator. We generate a non-classical superposition of the zero- and one-phonon Fock states and map this and other states using Wigner tomography9–14. Such precise, programmable quantum control is essential to a range of applications of surface acoustic waves in the quantum limit, including the coupling of disparate quantum systems15,16.

Suggested Citation

  • K. J. Satzinger & Y. P. Zhong & H.-S. Chang & G. A. Peairs & A. Bienfait & Ming-Han Chou & A. Y. Cleland & C. R. Conner & É. Dumur & J. Grebel & I. Gutierrez & B. H. November & R. G. Povey & S. J. Whi, 2018. "Quantum control of surface acoustic-wave phonons," Nature, Nature, vol. 563(7733), pages 661-665, November.
  • Handle: RePEc:nat:nature:v:563:y:2018:i:7733:d:10.1038_s41586-018-0719-5
    DOI: 10.1038/s41586-018-0719-5
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    Citations

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    Cited by:

    1. Simon Hönl & Youri Popoff & Daniele Caimi & Alberto Beccari & Tobias J. Kippenberg & Paul Seidler, 2022. "Microwave-to-optical conversion with a gallium phosphide photonic crystal cavity," Nature Communications, Nature, vol. 13(1), pages 1-9, December.
    2. Germain Tobar & Sreenath K. Manikandan & Thomas Beitel & Igor Pikovski, 2024. "Detecting single gravitons with quantum sensing," Nature Communications, Nature, vol. 15(1), pages 1-14, December.
    3. Agnetta Y. Cleland & E. Alex Wollack & Amir H. Safavi-Naeini, 2024. "Studying phonon coherence with a quantum sensor," Nature Communications, Nature, vol. 15(1), pages 1-7, December.
    4. Weitao Yuan & Chenwen Yang & Danmei Zhang & Yang Long & Yongdong Pan & Zheng Zhong & Hong Chen & Jinfeng Zhao & Jie Ren, 2021. "Observation of elastic spin with chiral meta-sources," Nature Communications, Nature, vol. 12(1), pages 1-9, December.
    5. Ji-Qian Wang & Zi-Dong Zhang & Si-Yuan Yu & Hao Ge & Kang-Fu Liu & Tao Wu & Xiao-Chen Sun & Le Liu & Hua-Yang Chen & Cheng He & Ming-Hui Lu & Yan-Feng Chen, 2022. "Extended topological valley-locked surface acoustic waves," Nature Communications, Nature, vol. 13(1), pages 1-8, December.
    6. J. M. Kitzman & J. R. Lane & C. Undershute & P. M. Harrington & N. R. Beysengulov & C. A. Mikolas & K. W. Murch & J. Pollanen, 2023. "Phononic bath engineering of a superconducting qubit," Nature Communications, Nature, vol. 14(1), pages 1-7, December.
    7. Arjun Iyer & Yadav P. Kandel & Wendao Xu & John M. Nichol & William H. Renninger, 2024. "Coherent optical coupling to surface acoustic wave devices," Nature Communications, Nature, vol. 15(1), pages 1-9, December.

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