Extension of filament propagation in water with Bessel-Gaussian beams

Kaya, Gamze; Kaya, Necati; Sayrac, M.; Boran, Y.; Strohaber, James; Kolomenskii, A.A.; Amani, Mahmood; Schuessler, H. A.

doi:10.1063/1.4943397

Cited by 13 publications

(6 citation statements)

References 38 publications

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“…Nearly two decades of experimental and theoretical studies of filamentation in air with near-infrared femtosecond laser pulses, have elucidated the principal physical processes involved 15 – 20 . Most studies have been performed with laser powers sufficient for the eventual formation of a filament, in air stabilized by partial ionization and the consequential impact of the liberated electrons on the beam propagation.…”

Section: Introductionmentioning

confidence: 99%

Free-Space Nonlinear Beam Combining for High Intensity Projection

Fairchild

Walasik

Kepler

et al. 2017

Sci Rep

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The controlled interaction of two high intensity beams opens new degrees of freedom for manipulating electromagnetic waves in air. The growing number of applications for laser filaments requires fine control of their formation and propagation. We demonstrate, experimentally and theoretically, that the attraction and fusion of two parallel ultrashort beams with initial powers below the critical value (70% P critical), in the regime where the non-linear optical characteristics of the medium become dominant, enable the eventual formation of a filament downstream. Filament formation is delayed to a predetermined distance in space, defined by the initial separation between the centroids, while still enabling filaments with controllable properties as if formed from a single above-critical power beam. This is confirmed by experimental and theoretical evidence of filament formation such as the individual beam profiles and the supercontinuum emission spectra associated with this interaction.

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Section: Introductionmentioning

confidence: 99%

Free-Space Nonlinear Beam Combining for High Intensity Projection

Fairchild

Walasik

Kepler

et al. 2017

Sci Rep

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“…An intense femtosecond pulse filamentation and propagation were experimentally studied in water for Bessel-Gaussian beams with different numbers of radial modal lobes . [21]. The filament propagation length increased with increasing number of lobes under the conditions of the same peak intensity, pulse duration, and the size of the central peak of the incident beam, suggesting that the radial modal lobes feed energy to the filaments formed by the central intensity peak.…”

Section: Introductionmentioning

confidence: 89%

“…There are several possibilities investigated to control the spatial and temporal characteristics of the filamentation process and resulting white-light generation [11,[18][19][20][21]. By changing the transverse spatial phase of an initial Gaussian beam with a computer-generated hologram technique and a spatial light modulator [11] beams with phase discontinuities and steeper intensity gradients were created.…”

Section: Introductionmentioning

confidence: 99%

Field-free molecular alignment control of filamentation

Kaya¹

2017

Turk J Phys

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Abstract:With an approach of controlling the nonlinearity of medium rather than the light field, the effect of field-free molecular alignment on filamentation and resulting white-light generation is studied. This is done by measuring the rotational wavepacket evolution of nitrogen molecules after passing of a femtosecond laser pump pulse by observing the nonlinear propagation dynamics of a variably delayed filament-producing probe pulse.

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“…The critical power for self-focusing for an elliptical beam was found to be greater than a beam with cylindrical symmetry, and the role of the elliptical intensity distribution was discussed in details [14][15][16][17][18]. Studies also show that controlling and organizing filament formations are possible by inserting slits and meshes into the beam path of an intense laser pulse [19], creating Fresnel diffraction from a circular aperture [20], applying amplitude [21,22] and phase [23,24] modulation of the beam field, combining the phase plates [25], producing high order Hermite Gaussian beams [26] and Bessel Gaussian beams [27], probing nonlinear molecular alignment [28][29][30] and crossing two femtosecond laser beams [31] etc.…”

Section: Introductionmentioning

confidence: 99%

Controlled formation of femtosecond laser-induced filaments in water

Kaya

2020

Eur. Phys. J. D

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Controlled formation of femtosecond laser-induced filaments in water was introduced and demonstrated experimentally, based on the transverse spatial phase change in the initial femtosecond laser pulse. Single or multi-filament formations were controlled and organized by switching on and off through a computer-controlled transverse spatial phase mask on a liquid crystal Spatial Light Modulator (SLM). We introduced a π phase step on SLM, which distributed laser intensity non-uniformly and in certain locations peak intensity exceeded the critical threshold, and filaments were formed in the peaks of the intensity. The setup with controllable phase shift on SLM may have great flexibility and convenience in controls of filament formation.

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Extension of filament propagation in water with Bessel-Gaussian beams

Cited by 13 publications

References 38 publications

Free-Space Nonlinear Beam Combining for High Intensity Projection

Free-Space Nonlinear Beam Combining for High Intensity Projection

Field-free molecular alignment control of filamentation

Controlled formation of femtosecond laser-induced filaments in water

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