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Random anti-lasing through coherent perfect absorption in a disordered medium

Author

Listed:
  • Kevin Pichler

    (Vienna University of Technology (TU Wien))

  • Matthias Kühmayer

    (Vienna University of Technology (TU Wien))

  • Julian Böhm

    (Université Côte d’Azur, CNRS)

  • Andre Brandstötter

    (Vienna University of Technology (TU Wien))

  • Philipp Ambichl

    (Vienna University of Technology (TU Wien))

  • Ulrich Kuhl

    (Université Côte d’Azur, CNRS)

  • Stefan Rotter

    (Vienna University of Technology (TU Wien))

Abstract

Non-Hermitian wave engineering is a recent and fast-moving field that examines both fundamental and application-oriented phenomena1–7. One such phenomenon is coherent perfect absorption8–11—an effect commonly referred to as ‘anti-lasing’ because it corresponds to the time-reversed process of coherent emission of radiation at the lasing threshold (where all radiation losses are exactly balanced by the optical gain). Coherent perfect absorbers (CPAs) have been experimentally realized in several setups10–18, with the notable exception of a CPA in a disordered medium (a medium without engineered structure). Such a ‘random CPA’ would be the time-reverse of a ‘random laser’19,20, in which light is resonantly enhanced by multiple scattering inside a disorder. Because of the complexity of this scattering process, the light field emitted by a random laser is also spatially complex and not focused like a regular laser beam. Realizing a random CPA (or ‘random anti-laser’) is therefore challenging because it requires the equivalent of time-reversing such a light field in all its degrees of freedom to create coherent radiation that is perfectly absorbed when impinging on a disordered medium. Here we use microwave technology to build a random anti-laser and demonstrate its ability to absorb suitably engineered incoming radiation fields with near-perfect efficiency. Because our approach to determining these field patterns is based solely on far-field measurements of the scattering properties of a disordered medium, it could be suitable for other applications in which waves need to be perfectly focused, routed or absorbed.

Suggested Citation

  • Kevin Pichler & Matthias Kühmayer & Julian Böhm & Andre Brandstötter & Philipp Ambichl & Ulrich Kuhl & Stefan Rotter, 2019. "Random anti-lasing through coherent perfect absorption in a disordered medium," Nature, Nature, vol. 567(7748), pages 351-355, March.
    • Handle: RePEc:nat:nature:v:567:y:2019:i:7748:d:10.1038_s41586-019-0971-3
    DOI: 10.1038/s41586-019-0971-3
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    Cited by:

    1. Sungsam Kang & Yongwoo Kwon & Hojun Lee & Seho Kim & Jin Hee Hong & Seokchan Yoon & Wonshik Choi, 2023. "Tracing multiple scattering trajectories for deep optical imaging in scattering media," Nature Communications, Nature, vol. 14(1), pages 1-12, December.
    2. Georgy Ermolaev & Kirill Voronin & Denis G. Baranov & Vasyl Kravets & Gleb Tselikov & Yury Stebunov & Dmitry Yakubovsky & Sergey Novikov & Andrey Vyshnevyy & Arslan Mazitov & Ivan Kruglov & Sergey Zhu, 2022. "Topological phase singularities in atomically thin high-refractive-index materials," Nature Communications, Nature, vol. 13(1), pages 1-9, December.
    3. Ying Li & Minghong Qi & Jiaxin Li & Pei-Chao Cao & Dong Wang & Xue-Feng Zhu & Cheng-Wei Qiu & Hongsheng Chen, 2022. "Heat transfer control using a thermal analogue of coherent perfect absorption," Nature Communications, Nature, vol. 13(1), pages 1-9, December.

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