Propagating light beams with widths down to and below the optical wavelength require bulky large-aperture lenses and remain focused only for micrometric distances. Here, we report the observation of light beams that violate this localization/depth-of-focus law by shrinking as they propagate, allowing resolution to be maintained and increased over macroscopic propagation lengths. In nanodisordered ferroelectrics we observe a non-paraxial propagation of a sub-micrometre-sized beam for over 1,000 diffraction lengths, the narrowest visible beam reported to date. This unprecedented effect is caused by the nonlinear response of a dipolar glass, which transforms the leading optical wave equation into a Klein-Gordon-type equation that describes a massive particle field. Our findings open the way to high-resolution optics over large depths of focus, and a route to merging bulk optics into nanodevices.

Delre, E., Di Mei, F., Parravicini, J., Parravicini, G., Agranat, A., Conti, C. (2015). Subwavelength anti-diffracting beams propagating over more than 1,000 Rayleigh lengths. NATURE PHOTONICS, 9(4), 228-232 [10.1038/nphoton.2015.21].

Subwavelength anti-diffracting beams propagating over more than 1,000 Rayleigh lengths

Parravicini, Jacopo;
2015

Abstract

Propagating light beams with widths down to and below the optical wavelength require bulky large-aperture lenses and remain focused only for micrometric distances. Here, we report the observation of light beams that violate this localization/depth-of-focus law by shrinking as they propagate, allowing resolution to be maintained and increased over macroscopic propagation lengths. In nanodisordered ferroelectrics we observe a non-paraxial propagation of a sub-micrometre-sized beam for over 1,000 diffraction lengths, the narrowest visible beam reported to date. This unprecedented effect is caused by the nonlinear response of a dipolar glass, which transforms the leading optical wave equation into a Klein-Gordon-type equation that describes a massive particle field. Our findings open the way to high-resolution optics over large depths of focus, and a route to merging bulk optics into nanodevices.
Articolo in rivista - Articolo scientifico
Electronic, Optical and Magnetic Materials; Atomic and Molecular Physics, and Optics
English
2015
9
4
228
232
open
Delre, E., Di Mei, F., Parravicini, J., Parravicini, G., Agranat, A., Conti, C. (2015). Subwavelength anti-diffracting beams propagating over more than 1,000 Rayleigh lengths. NATURE PHOTONICS, 9(4), 228-232 [10.1038/nphoton.2015.21].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10281/122569
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