The laser lightning rod project

Produit, Thomas; Walch, Pierre; Herkommer, Clemens; Mostajabi, Amirhossein; Moret, Michel; Andral, Ugo; Šunjerga, Antonio; Azadifar, Mohammad; André, Yves-Bernard; Mahieu, B.; Haas, Walter; Esmiller, Bruno; Fournier, Gilles; Krötz, Peter; Metzger, Thomas; Michel, Knut; Mysyrowicz, A.; Rubinstein, Marcos; Rachidi, Farhad; Kasparian, Jérôme; Wolf, Jean‐Pierre; Houard, Aurélien

doi:10.1051/epjap/2020200243

Cited by 29 publications

(20 citation statements)

References 66 publications

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“…A statistically significant number of electric events synchronized with the laser pulses of high-power Teramobile 29 facility was reported after real-scale experiments 30 . This research is continued nowadays, and a laser lightning rod based on the plasma and the low-density channel produced by a filament of 1.03-µm, ∼1-ps, Joule-level and high repetition rate laser is under investigation 31 .…”

mentioning

confidence: 99%

Remote triggering of air-gap discharge by a femtosecond laser filament and postfilament at distances up to 80 m

Kosareva

Mokrousova

Panov

et al. 2021

Applied Physics Letters

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We experimentally observed a laser-induced remote high-voltage discharge triggering between two needle electrodes with half-a-cm spacing. The discharge was initiated by a 744-nm, 90-fs, 6-mJ laser pulse undergoing filamentation in air. For the direct voltage below the self-breakdown threshold, triggering of air-gap discharge was synchronized with 10-Hz laser repetition rate and occurred between 40 and 80 m of the propagation path. No discharge guiding was observed. The experimentally registered and simulated remote triggering probability was above 80% in the range of 40-65 m from laser output, and about 50% in the range of 65-80 m. The probability decreases as the postfilament hot spot diverges with simultaneous increase of stochastic laser beam wandering.

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confidence: 99%

Remote triggering of air-gap discharge by a femtosecond laser filament and postfilament at distances up to 80 m

Kosareva

Mokrousova

Panov

et al. 2021

Applied Physics Letters

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“…We simulate our experiment by numerically solving coupled-mode Helmholtz equations for a beam propagating through a saturable self-focusing medium and obtain good agreement with experiment. Our results add to the growing understanding of rogue behavior [4,5], and they bear upon the use of polarization-structured beams to control nonlinear self-focusing processes in remote sensing [11,13,14], optical communications [25], and laser engineering [50]. The extent to which polarization structure is maintained during nonlinear self-focusing warrants further study.…”

Section: Discussionmentioning

confidence: 59%

“…Optical communications [10], remote sensing, and lightning strike control [11][12][13][14] are a few technologies that rely upon a careful understanding of the interplay between linear and nonlinear propagation effects. Encoding information in the orbital angular momentum (OAM) of light is a promising way to increase the information capacity of optical communication channels [15][16][17][18].…”

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confidence: 99%

Suppression of Nonlinear Optical Rogue Wave Formation Using Polarization-Structured Beams

Black¹,

Choudhary²,

Arroyo-Rivera³

et al. 2022

Preprint

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A nonlinear self-focusing material can amplify random small-amplitude phase modulations present in an optical beam, leading to the formation of amplitude singularities commonly referred to as optical caustics. By imposing polarization structuring on the beam, we demonstrate the suppression of amplitude singularities caused by nonlinear self-phase modulation. Our results are the first to indicate that polarization-structured beams can suppress nonlinear caustic formation in a saturable self-focusing medium and add to the growing understanding of catastrophic self-focusing effects in beams containing polarization structure.

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“…During filamentation, the laser radiation localizes into single or multiple filaments due to the dynamic equilibrium between Kerr self-focusing and defocusing in the self-induced plasma [7][8][9][10][11][12]. Applications of filamentation in air include atmospheric remote sensing [13][14][15][16][17][18], triggering and guiding of high-voltage discharges [19][20][21][22], lightning control [23][24][25], filament-induced breakdown spectroscopy [26][27][28][29].…”

Section: Introductionmentioning

confidence: 99%

Tracing Evolution of Angle-Wavelength Spectrum along the 40-m Postfilament in Corridor Air

et al. 2021

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Postfilamentation channel resulting from filamentation of freely propagating 744-nm, 5-mJ, 110-fs pulse in the corridor air is examined experimentally and in simulations. The longitudinal extension of postfilament was determined to be 55–95 m from the compressor output. Using single-shot angle-wavelength spectra measurements, we observed a series of red-shifted maxima in the spectrum, localized on the beam axis with the divergence below 0.5 mrad. In the range 55–70 m, the number of maxima and their red-shift increase with the distance reaching 1 μm, while the pulse duration measured by the autocorrelation technique is approximately constant. Further on, for distances larger than 70 m and up to 95 m, the propagation is characterized by the suppressed beam divergence and unchanged pulse spectrum. The pulse duration increases due to the normal air dispersion.

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The laser lightning rod project

Cited by 29 publications

References 66 publications

Remote triggering of air-gap discharge by a femtosecond laser filament and postfilament at distances up to 80 m

Remote triggering of air-gap discharge by a femtosecond laser filament and postfilament at distances up to 80 m

Suppression of Nonlinear Optical Rogue Wave Formation Using Polarization-Structured Beams

Tracing Evolution of Angle-Wavelength Spectrum along the 40-m Postfilament in Corridor Air

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