Triggering extreme events at the nanoscale in photonic seas

Triggering extreme events at the nanoscale in photonic seas

Hurricanes, tsunamis, rogue waves and tornadoes are rare natural phenomena that embed an exceptionally large amount of energy, which appears and quickly disappears in a probabilistic fashion. This makes them difficult to predict and hard to generate on demand. Here we demonstrate that we can trigger...

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Bibliographic Details
Published in:Nature physics Vol. 11; no. 4; pp. 358 - 363
Main Authors: Liu, C., van der Wel, R. E. C., Rotenberg, N., Kuipers, L., Krauss, T. F., Di Falco, A., Fratalocchi, A.
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 01-04-2015
Nature Publishing Group
Subjects:
639/624
639/766
639/925
Atomic
Bandwidth
Classical and Continuum Physics
Complex Systems
Condensed Matter Physics
Construction
Dielectric properties
Energy
Energy of formation
Fields (mathematics)
Hurricanes
Imaging
Mathematical and Computational Physics
Molecular
Nanostructured materials
Optical and Plasma Physics
Physics
Probability
Synchronism
Theoretical
Tornadoes
Tsunamis
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Summary:Hurricanes, tsunamis, rogue waves and tornadoes are rare natural phenomena that embed an exceptionally large amount of energy, which appears and quickly disappears in a probabilistic fashion. This makes them difficult to predict and hard to generate on demand. Here we demonstrate that we can trigger the onset of rare events akin to rogue waves controllably, and systematically use their generation to break the diffraction limit of light propagation. We illustrate this phenomenon in the case of a random field, where energy oscillates among incoherent degrees of freedom. Despite the low energy carried by each wave, we illustrate how to control a mechanism of spontaneous synchronization, which constructively builds up the spectral energy available in the whole bandwidth of the field into giant structures, whose statistics is predictable. The larger the frequency bandwidth of the random field, the larger the amplitude of rare events that are built up by this mechanism. Our system is composed of an integrated optical resonator, realized on a photonic crystal chip. Through near-field imaging experiments, we record confined rogue waves characterized by a spatial localization of 206 nm and with an ultrashort duration of 163 fs at a wavelength of 1.55 μm. Such localized energy patterns are formed in a deterministic dielectric structure that does not require nonlinear properties. Rogue waves in a sea of photons can localize light beyond the diffraction limit, but their rarity makes them difficult to study. These events can now be controllably triggered in a photonic crystal resonator.
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ISSN:1745-2473
1745-2481
DOI:10.1038/nphys3263