Physics and applications of atmospheric nonlinear optics and filamentation

Abstract: Abstract:We review the properties and applications of ultrashort laser pulses in the atmosphere, with a particular focus on filamentation. Filamentation is a non-linear propagation regime specific of ultrashort and ultraintense laser pulses in the atmosphere. Typical applications include remote sensing of atmospheric gases and aerosols, lightning control, laserinduced spectroscopy, coherent anti-stokes Raman scattering, and the generation of sub-THz radiation. References and Links 1. P. L. Kelley, "Self-focusi… Show more

“…This finding provides a better understanding of filamentation, and therefore allows to improve its modelling. It further confirms the relevance of the measured HOKE [8,9], with implications ranging from spectral broadening in optical fibers [25] to the generation of few-cycle pulses [26], atmospheric applications [5][6][7], or fermionic light [27].…”

“…Filamentation [1][2][3][4] is a self-guided propagation regime typical of high-power lasers, offering spectacular potential applications [5] like rainmaking [6] and lightning control [7]. We recently challenged its long-established mechanism by measuring the higher order Kerr effect (HOKE) in gases, implying that the non-linear refractive index must be written as ∆n Kerr = n 2j I j , where the non-linear indices n 2j are related to the (2j + 1) th electric susceptibility χ (2j+1) .…”

Transition from Plasma-Driven to Kerr-Driven Laser Filamentation

“…This finding provides a better understanding of filamentation, and therefore allows to improve its modelling. It further confirms the relevance of the measured HOKE [8,9], with implications ranging from spectral broadening in optical fibers [25] to the generation of few-cycle pulses [26], atmospheric applications [5][6][7], or fermionic light [27].…”

“…Filamentation [1][2][3][4] is a self-guided propagation regime typical of high-power lasers, offering spectacular potential applications [5] like rainmaking [6] and lightning control [7]. We recently challenged its long-established mechanism by measuring the higher order Kerr effect (HOKE) in gases, implying that the non-linear refractive index must be written as ∆n Kerr = n 2j I j , where the non-linear indices n 2j are related to the (2j + 1) th electric susceptibility χ (2j+1) .…”

Transition from Plasma-Driven to Kerr-Driven Laser Filamentation

“…This finding confirms that our understanding of laser filamentation has to be updated, which will in particular impact the determination of the optimal conditions for the potential applications [2,15] of laser filamentation, like cloudmaking [16] and lightning control [17].…”

“…Laser filamentation [1,2] is due to a dynamic balance between self-focusing by the Kerr effect, and self-defocusing non-linearities of higher orders. While the contribution of the laser-generated plasma to the self-defocusing has been identified more than a decade ago, the contribution of the higherorder Kerr effect (HOKE) [3,4] to self-defocusing is still actively debated.…”

Higher-order Kerr effects improve quantitative modelling of harmonics generation and laser filamentation

“…A discharge obtained with a positive polarity on the HV electrode corresponds to the propagation of an ascending negative leader, and vice versa. As a consequence of the differences between negative and positive leader characteristics and propagation speed, [4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19] results obtained with positive and negative polarities are quite different. Estimation of the negative discharge velocity based on the delay between the laser and the spark gives V -= 2.5x10 6 m/s, in good agreement with previously reported values for laser guided negative leader velocities.…”

Triggering, guiding and deviation of long air spark discharges with femtosecond laser filament