Conical Emission, Pulse Splitting, and X-Wave Parametric Amplification in Nonlinear Dynamics of Ultrashort Light Pulses

Faccio, Daniele; Porras, Miguel A.; Dubietis, A.; Bragheri, Francesca; Couairon, Arnaud; Trapani, P. Di

doi:10.1103/physrevlett.96.193901

Cited by 184 publications

(123 citation statements)

References 16 publications

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“…Therefore all subsequent features of the filament propagation in the regime of normal GVD, i.e. pulse splitting, conical emission and any nonlinear interactions, may be interpreted assuming the pulses as spontaneously occurring nonlinear X-waves [99]. Consequently, the formation and propagation features of spatiotemporal light bullets in the regime of anomalous GVD may be interpreted in terms of nonlinear O-waves [83].…”

Section: Conical Emissionmentioning

confidence: 99%

Ultrafast supercontinuum generation in bulk condensed media

Dubietis¹,

Tamošauskas²,

Šuminas³

et al. 2017

Lith. J. Phys.

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166

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Nonlinear propagation of intense femtosecond laser pulses in bulk transparent media leads to a specific propagation regime, termed femtosecond filamentation, which in turn produces dramatic spectral broadening, or superbroadening, termed supercontinuum generation. Femtosecond supercontinuum generation in transparent solids represents a compact, efficient and alignment-insensitive technique for generation of coherent broadband radiation at various parts of the optical spectrum, which finds numerous applications in diverse fields of modern ultrafast science. During recent years, this research field has reached a high level of maturity, both in understanding of the underlying physics and in achievement of exciting practical results. In this paper we overview the state-of-the-art femtosecond supercontinuum generation in various transparent solid-state media, ranging from wide-bandgap dielectrics to semiconductor materials and in various parts of the optical spectrum, from the ultraviolet to the mid-infrared spectral range. A particular emphasis is given to the most recent experimental developments: multioctave supercontinuum generation with pumping in the mid-infrared spectral range, spectral control, power and energy scaling of broadband radiation and the development of simple, flexible and robust pulse compression techniques, which deliver few optical cycle pulses and which could be readily implemented in a variety of modern ultrafast laser systems.

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Section: Conical Emissionmentioning

confidence: 99%

Ultrafast supercontinuum generation in bulk condensed media

Dubietis¹,

Tamošauskas²,

Šuminas³

et al. 2017

Lith. J. Phys.

Self Cite

166

View full text Add to dashboard Cite

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“…The stabilization mechanism is given by higher order cascaded nonlinearities in normal dispersion. Notably, collapse-free propagation in a nonlinear Kerr material with normal dispersion also allows the generation of X waves [20,35,36], optical pulses with a characteristic X shape in the space-time or angle-wavelength domain. Although the study of X waves is beyond the scope of this Letter, the interpretation of the nonlinear phase exchange among the components in terms of higher order defocusing nonlinearity opens up new perspectives for understanding such waves.…”

Section: Fig 2 (Color Online) (A) Total Photon Fluxmentioning

confidence: 99%

Collapse Arrest in Instantaneous Kerr Media via Parametric Interactions

et al. 2014

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“…Further modelling should include realistic intensity flux [44,45] and intensity shapes [46], and advanced phase profile such as the recently studied spatio-temporal optical vortices [30]. Such features will expectedly improve the description of inter-filament interactions.…”

mentioning

confidence: 99%

Gas-Solid Phase Transition in Laser Multiple Filamentation

et al. 2017

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While propagating in transparent media, near-infrared multi-terawatt (TW) laser beams break up in a multitude of filaments of typically 100-200 um diameter with peak intensities as high as 10 to 100 TW/cm 2 . We observe a phase transition at incident beam intensities of 0.4 TW/cm 2 , where the interaction between filaments induce solid-like 2-dimensional crystals with a 2.7 mm lattice constant, independent of the initial beam diameter. Below 0.4 TW/cm 2 , we evidence a mixed phase state in which some filaments are closely packed in localized clusters, nucleated on inhomogeneities (seeds) in the transverse intensity profile of the beam, and other are sparse with almost no interaction with their neighbors, similar to a gas. This analogy with a thermodynamic gas-solid phase transition is confirmed by calculating the interaction Hamiltonian between neighboring filaments, which takes into account the effect of diffraction, Kerr self-focusing and plasma generation. The shape of the effective potential is close to a Morse potential with an equilibrium bond length close to the observed value.Many physical systems are well described by statistical models driven by nearest-neighbor interactions, such as spin models [1][2][3]. Recently, we showed that the formation of multiple filamentation patterns in high-power ultrashort laser pulses also belong to this category [4,5].Laser filaments are produced in high-power, ultrashort laser pulses propagating in air or other transparent media [6][7][8] by a dynamic balance between Kerr selffocusing, and defocusing by higher-order non-linear effects including the ionization of the medium and other polarization saturation terms [9,10]. At 800 nm, this balance clamps the filaments intensity to typically 50 TW/cm 2 [11,12]. Filaments cannot be considered as virtual optical fibers guiding the light within their core: they continuously interact and exchange energy with the photon bath surrounding them [13][14][15][16]. This photon bath, also known as energy reservoir [13,17,18], plays a key role in the filamentation process. In particular, the photon bath feeds the filament and balances its energy losses, allowing it to self-heal after an obstacle [14][15][16] or extend its propagation distance [19].In the case of multifilamentation, the laser energy reservoir also mediates interactions between neighboring filaments [20][21][22][23][24][25][26]. This interaction is attractive if the filaments are in phase, and repulsive if they are in antiphase [27,28], corresponding to constructive and destructive interferences in the photon bath, respectively. Previous theoretical and experimental studies have shown that the relative phase between filaments is mainly randomly driven by intensity fluctuations during the collapse [29] and is then stabilized for the filaments propagating after the collapse [30].Recently we showed that at laser powers exceeding 100 TW, this mutual interaction limits the density of filaments in the transverse beam profile [31], resulting in the * corresponding author jean-pi...

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Conical Emission, Pulse Splitting, and X-Wave Parametric Amplification in Nonlinear Dynamics of Ultrashort Light Pulses

Cited by 184 publications

References 16 publications

Ultrafast supercontinuum generation in bulk condensed media

Ultrafast supercontinuum generation in bulk condensed media

Collapse Arrest in Instantaneous Kerr Media via Parametric Interactions

Gas-Solid Phase Transition in Laser Multiple Filamentation

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