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Quantum control of a nanoparticle optically levitated in cryogenic free space

Author

Listed:
  • Felix Tebbenjohanns

    (Photonics Laboratory, ETH Zürich)

  • M. Luisa Mattana

    (Photonics Laboratory, ETH Zürich)

  • Massimiliano Rossi

    (Photonics Laboratory, ETH Zürich)

  • Martin Frimmer

    (Photonics Laboratory, ETH Zürich)

  • Lukas Novotny

    (Photonics Laboratory, ETH Zürich
    Quantum Center, ETH Zurich)

Abstract

Tests of quantum mechanics on a macroscopic scale require extreme control over mechanical motion and its decoherence1–3. Quantum control of mechanical motion has been achieved by engineering the radiation–pressure coupling between a micromechanical oscillator and the electromagnetic field in a resonator4–7. Furthermore, measurement-based feedback control relying on cavity-enhanced detection schemes has been used to cool micromechanical oscillators to their quantum ground states8. In contrast to mechanically tethered systems, optically levitated nanoparticles are particularly promising candidates for matter-wave experiments with massive objects9,10, since their trapping potential is fully controllable. Here we optically levitate a femtogram (10−15 grams) dielectric particle in cryogenic free space, which suppresses thermal effects sufficiently to make the measurement backaction the dominant decoherence mechanism. With an efficient quantum measurement, we exert quantum control over the dynamics of the particle. We cool its centre-of-mass motion by measurement-based feedback to an average occupancy of 0.65 motional quanta, corresponding to a state purity of 0.43. The absence of an optical resonator and its bandwidth limitations holds promise to transfer the full quantum control available for electromagnetic fields to a mechanical system. Together with the fact that the optical trapping potential is highly controllable, our experimental platform offers a route to investigating quantum mechanics at macroscopic scales11.

Suggested Citation

  • Felix Tebbenjohanns & M. Luisa Mattana & Massimiliano Rossi & Martin Frimmer & Lukas Novotny, 2021. "Quantum control of a nanoparticle optically levitated in cryogenic free space," Nature, Nature, vol. 595(7867), pages 378-382, July.
  • Handle: RePEc:nat:nature:v:595:y:2021:i:7867:d:10.1038_s41586-021-03617-w
    DOI: 10.1038/s41586-021-03617-w
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    Citations

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    Cited by:

    1. Yuanbin Jin & Kunhong Shen & Peng Ju & Xingyu Gao & Chong Zu & Alejandro J. Grine & Tongcang Li, 2024. "Quantum control and Berry phase of electron spins in rotating levitated diamonds in high vacuum," Nature Communications, Nature, vol. 15(1), pages 1-9, December.
    2. Jianan Yin & Yang Yan & Mulin Miao & Jiayin Tang & Jiali Jiang & Hui Liu & Yuhan Chen & Yinxian Chen & Fucong Lyu & Zhengyi Mao & Yunhu He & Lei Wan & Binbin Zhou & Jian Lu, 2024. "Diamond with Sp2-Sp3 composite phase for thermometry at Millikelvin temperatures," Nature Communications, Nature, vol. 15(1), pages 1-8, December.
    3. Jingkun Guo & Jin Chang & Xiong Yao & Simon Gröblacher, 2023. "Active-feedback quantum control of an integrated low-frequency mechanical resonator," Nature Communications, Nature, vol. 14(1), pages 1-9, December.
    4. Mitsuyoshi Kamba & Ryoga Shimizu & Kiyotaka Aikawa, 2023. "Nanoscale feedback control of six degrees of freedom of a near-sphere," Nature Communications, Nature, vol. 14(1), pages 1-9, December.
    5. Fabrizio Berritta & Torbjørn Rasmussen & Jan A. Krzywda & Joost Heijden & Federico Fedele & Saeed Fallahi & Geoffrey C. Gardner & Michael J. Manfra & Evert Nieuwenburg & Jeroen Danon & Anasua Chatterj, 2024. "Real-time two-axis control of a spin qubit," Nature Communications, Nature, vol. 15(1), pages 1-9, December.
    6. Christian Bærentsen & Sergey A. Fedorov & Christoffer Østfeldt & Mikhail V. Balabas & Emil Zeuthen & Eugene S. Polzik, 2024. "Squeezed light from an oscillator measured at the rate of oscillation," Nature Communications, Nature, vol. 15(1), pages 1-7, December.

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