Nonlinear Cavity and Frequency Comb Radiations Induced by Negative Frequency Field Effects

Lourés, Cristian Redondo; Faccio, Daniele; Biancalana, Fabio

doi:10.1103/physrevlett.115.193904

Phys. Rev. Lett.

2015

DOI: 10.1103/physrevlett.115.193904

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Nonlinear Cavity and Frequency Comb Radiations Induced by Negative Frequency Field Effects

Cristian Redondo Lourés

Daniele Faccio

Fabio Biancalana

Abstract: Starting from the infinite-dimensional Ikeda map, we derive an extended temporal Lugiato-Lefever equation that may account for the effects of the conjugate electromagnetic fields (also called 'negative frequency fields'). In the presence of nonlinearity in a ring cavity, these fields lead to new forms of modulational instability and resonant radiations. Numerical simulations based on the new extended Lugiato-Lefever model show that the negative-frequency resonant radiations emitted by ultrashort cavity soliton… Show more

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Cited by 12 publications

(12 citation statements)

References 27 publications

(49 reference statements)

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“…As a mean-field equation, it applies to other settings too, such as Fabry-Perot resonators and ring cavities, fully or partially filled with nonlinear materials [32], crystalline whispering-gallery-mode disk resonators [33], and photonic-crystal-fiber resonators pumped by a coherent continuous-wave input beam [34,35]. In these contexts, the LL equation has been widely used to model Kerr frequency combs [36,37,38,39,40], with applications to optical metrology [41], highprecision spectroscopy [42,43], optical atomic clocks [44,45], phase evolution in pulse trains [46,47], optical communications [48], synthesis of arbitrary optical waveforms [49,50], and radio-frequency photonics [51]. A review of the development of various applications of the LL equations has been published recently [52].…”

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confidence: 99%

Localized solutions of Lugiato-Lefever equations with focused pump

Cardoso

Salasnich

Malomed

2017

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Lugiato-Lefever (LL) equations in one and two dimensions (1D and 2D) accurately describe the dynamics of optical fields in pumped lossy cavities with the intrinsic Kerr nonlinearity. The external pump is usually assumed to be uniform, but it can be made tightly focused too–in particular, for building small pixels. We obtain solutions of the LL equations, with both the focusing and defocusing intrinsic nonlinearity, for 1D and 2D confined modes supported by the localized pump. In the 1D setting, we first develop a simple perturbation theory, based in the sech ansatz, in the case of weak pump and loss. Then, a family of exact analytical solutions for spatially confined modes is produced for the pump focused in the form of a delta-function, with a nonlinear loss (two-photon absorption) added to the LL model. Numerical findings demonstrate that these exact solutions are stable, both dynamically and structurally (the latter means that stable numerical solutions close to the exact ones are found when a specific condition, necessary for the existence of the analytical solution, does not hold). In 2D, vast families of stable confined modes are produced by means of a variational approximation and full numerical simulations.

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Localized solutions of Lugiato-Lefever equations with focused pump

Cardoso

Salasnich

Malomed

2017

Sci Rep

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“…research on microlasers [3], filters for communication technology [4] or single molecule sensing [5]. Furthermore, the research on micro-combs [6][7][8] and optomechanics [9,10] benefits from the progresses made in the field of optical microresonators. Established examples of optical microcavites are microdisks [3,11], microspheres [12,13] and microtoroids [14,15] which confine light in whispering gallery modes with high quality factors Q.…”

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Three-dimensional limaçon: Properties and applications

2017

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We perform electromagnetic wave simulations of fully three-dimensional optical Limaçon-microcavities, one basis for their future applications in microlasers and photonic devices. The analysis of the three-dimensional modes and far-fields reveals an increase of the quality factors as compared to the two-dimensional case. The structure of the far-field in the third dimension shows pronounced maxima in the emission directionality inclined to the resonator plane which may be exploited for coupling the resonator modes to the environment. This triggers ideas for technical applications, like the suggested sensor that can detect small changes in the environment based on changes in the emission profile. [14,15] which confine light in whispering gallery modes with high quality factors Q. The first microdisk-based microlasers had the drawback of isotropic light emission because of rotational symmetry. In order to observe a directional laser emission, deformed microcavities were investigated [16][17][18]. A promising shape to combine directional emission and high quality factors is the Limaçon-shape [19]. Here, ray and wave calculations based on a two-dimensional model system agree very well with the experimentally observed far-field characteristics [20][21][22][23].In reality, however, microcavities are three-dimensional (3D) objects with finite heights. This third dimension will be especially important when the cavity sizes are further reduced and both cavity height h and radius R become comparable to the wavelength [24,25]. Here, we systematically study 3D microcavities of Limaçon-shape, see left inset of FIG. 1. Its cross section in the x-y-plane is given in polar coordinates (r, φ), cf. FIG. 1, bywith mean Radius R and deformation parameter δ. We set δ = 0.43, a value known [19] to yield a highly directional far-field emission for two-dimensional (2D) cavities with refractive index n = 3.3 embedded in vacuum (n 0 = 1) as used here. We first discuss modes and farfields of 3D Limaçon cavities of varying height to radius ratio h/R, followed by outlining a sensor application based on the 3D character of the far field and its extreme sensitivity to tiny changes in the refractive index. Using MEEP [26], a free finite-difference time-domain (FDTD) software package, 3D electromagnetic wave simulations have been performed to calculate the normalized frequencies Ω = kR = Re(ω)R/c, with ω being a complex frequency and c the speed of light, the quality factors Q = −0.5Re(ω)/Im(ω), the distributions of the electric field component E z (x, y, z) (modes) and the farfield intensity I(φ, θ). As our focus is on wavelength-scale cavities, kR ranges from 1.9 up to 10.7, with k = 2π/λ being the wave number and λ the wavelength in vacuum. We use a E z -point-dipole source to excite the modes and focus on the study of TM-polarized modes.We first discuss the analogies between the structures of modes of the 2D and 3D Limaçon cavity, respectively. An example of a 2D mode and the (x, y)-cross section of a 3D mode are shown in FIG. 2 (a) and (b)...

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“…In a recent work, Conforti et al proposed an equation for the analytic signal of an electric field that is formally similar to the NLSE but does not suffer from many of the limitations of the latter [17] and only relies the reasonable assumption of neglecting backward propagating waves [18]. This equation has been found to predict some features of the nonlinear interaction between light and matter that were not present in the original NLSE, related to the so-called negative frequency components of the electromagnetic pulse [19,[21][22][23][24]. In their paper, the authors discuss new phase matching conditions that arise from the new nonlinear polarisation terms in their equation, and theoretically predict the emission of what has been dubbed negative resonant radiation (NRR) and third-harmonic resonant radiation (THRR).…”

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“…Equation (1) has been successfully applied to optical fibers, crystals [17,22] and fiber or microring cavities [23].…”

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confidence: 99%

See 1 more Smart Citation

Superresonant Radiation Stimulated by Higher Harmonics

et al. 2017

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Solitons propagating in media with higher order dispersion will shed radiation known as dispersive wave or resonant radiation, with applications in frequency broadening, deep UV sources for spectroscopy or simply fundamental studies of soliton physics. Starting from a recently proposed equation that models the behaviour of ultrashort optical pulses in nonlinear materials using the analytic signal, we find that the resonant radiation associated with the third-harmonic generation term of the equation is parametrically stimulated with an unprecedented gain. Resonant radiation levels, typically only a small fraction of the soliton, are now as intense as the soliton itself. The mechanism is quite universal and works also in normal dispersion and with harmonics higher than the third. We report experimental hints of this super-resonant radiation stimulated by the fifth harmonic in diamond.

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Nonlinear Cavity and Frequency Comb Radiations Induced by Negative Frequency Field Effects

Cited by 12 publications

References 27 publications

Localized solutions of Lugiato-Lefever equations with focused pump

Localized solutions of Lugiato-Lefever equations with focused pump

Three-dimensional limaçon: Properties and applications

Superresonant Radiation Stimulated by Higher Harmonics

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