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Quantum-enhanced nonlinear microscopy

Author

Listed:
  • Catxere A. Casacio

    (University of Queensland, St Lucia)

  • Lars S. Madsen

    (University of Queensland, St Lucia)

  • Alex Terrasson

    (University of Queensland, St Lucia)

  • Muhammad Waleed

    (University of Queensland, St Lucia)

  • Kai Barnscheidt

    (Universität Rostock)

  • Boris Hage

    (Universität Rostock)

  • Michael A. Taylor

    (The University of Queensland, St Lucia)

  • Warwick P. Bowen

    (University of Queensland, St Lucia)

Abstract

The performance of light microscopes is limited by the stochastic nature of light, which exists in discrete packets of energy known as photons. Randomness in the times that photons are detected introduces shot noise, which fundamentally constrains sensitivity, resolution and speed1. Although the long-established solution to this problem is to increase the intensity of the illumination light, this is not always possible when investigating living systems, because bright lasers can severely disturb biological processes2–4. Theory predicts that biological imaging may be improved without increasing light intensity by using quantum photon correlations1,5. Here we experimentally show that quantum correlations allow a signal-to-noise ratio beyond the photodamage limit of conventional microscopy. Our microscope is a coherent Raman microscope that offers subwavelength resolution and incorporates bright quantum correlated illumination. The correlations allow imaging of molecular bonds within a cell with a 35 per cent improved signal-to-noise ratio compared with conventional microscopy, corresponding to a 14 per cent improvement in concentration sensitivity. This enables the observation of biological structures that would not otherwise be resolved. Coherent Raman microscopes allow highly selective biomolecular fingerprinting in unlabelled specimens6,7, but photodamage is a major roadblock for many applications8,9. By showing that the photodamage limit can be overcome, our work will enable order-of-magnitude improvements in the signal-to-noise ratio and the imaging speed.

Suggested Citation

  • Catxere A. Casacio & Lars S. Madsen & Alex Terrasson & Muhammad Waleed & Kai Barnscheidt & Boris Hage & Michael A. Taylor & Warwick P. Bowen, 2021. "Quantum-enhanced nonlinear microscopy," Nature, Nature, vol. 594(7862), pages 201-206, June.
    • Handle: RePEc:nat:nature:v:594:y:2021:i:7862:d:10.1038_s41586-021-03528-w
    DOI: 10.1038/s41586-021-03528-w
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    Citations

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    Cited by:

    1. Ugo Zanforlin & Cosmo Lupo & Peter W. R. Connolly & Pieter Kok & Gerald S. Buller & Zixin Huang, 2022. "Optical quantum super-resolution imaging and hypothesis testing," Nature Communications, Nature, vol. 13(1), pages 1-9, December.
    2. Korenobu Matsuzaki & Tahei Tahara, 2022. "Superresolution concentration measurement realized by sub-shot-noise absorption spectroscopy," Nature Communications, Nature, vol. 13(1), pages 1-8, December.
    3. Sabrina D. Eder & Adam Fahy & Matthew G. Barr & J. R. Manson & Bodil Holst & Paul C. Dastoor, 2023. "Sub-resolution contrast in neutral helium microscopy through facet scattering for quantitative imaging of nanoscale topographies on macroscopic surfaces," Nature Communications, Nature, vol. 14(1), pages 1-10, December.
    4. Hubert S. Stokowski & Timothy P. McKenna & Taewon Park & Alexander Y. Hwang & Devin J. Dean & Oguz Tolga Celik & Vahid Ansari & Martin M. Fejer & Amir H. Safavi-Naeini, 2023. "Integrated quantum optical phase sensor in thin film lithium niobate," Nature Communications, Nature, vol. 14(1), pages 1-11, December.

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