Antiphase dynamics in pump-modulated multimode intracavity second-harmonic generation

Wang, Jingyi; Mandel, P.

doi:10.1088/1355-5111/8/1/003

Cited by 6 publications

(5 citation statements)

References 18 publications

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“…3. As it can be seen, for small nonlinearity, ǫ < 0.8 × 10 −4 , there is a rather good agreement between theoretically [Wang & Mandel, 1993] and numerically obtained results. However, when nonlinearity increases, 0.8 × 10 −4 < ǫ < 1.0 × 10 −4 , the minimal number of modes obtained in numerial simulations 5 is larger than the number predicted theoretically.…”

Section: Simplified Model -No Spatial-hole Buring Effectsupporting

confidence: 75%

“…The results presented in [James et al, 1990b, Magni et al, 1993, where the crosssaturation coefficient was assummed to be constant for all modes, are compared with the numerical data. It is shown that the theoretically obtained [Wang & Mandel, 1993] linear dependence of the minimal number of modes necassary for stabilization the laser output on the strength of nonlinearity agrees with the numerical solutions only in the case of sufficiently small nonlinearity. For larger values of nonlinearity, due to the cancellation of modes during the evolution, the minimal number of modes obtained by the numerical simulations is larger than the number which follows from the theoretical predictions.…”

Section: Introductionmentioning

confidence: 64%

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Elimination of Chaos in Multimode, Intracavity-Doubled Lasers in the Presence of Spatial Hole-Burning

Pietrzyk

Danailov

2001

Int. J. Bifurcation Chaos

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In this paper possibilities of a stabilization of large amplitude fluctuations in an intracavity-doubled solid-state laser are studied. The modification of the cross-saturation coefficient by the effect of spatial hole-burning is taken into account. The stabilization of the laser radiation by an increase of the number of modes, as proposed in [James et al., 1990b, Magni et al., 1993, is analyzed. It is found that when the crosssaturation coefficient is modulated by the spatial hole-burning the stabilization is not always possible. We propose a new way of obtaining a stable steady-state configuration based on an increase of the strength of nonlinearity, which leads to a strong cancellation of modes, so that during the evolution all of the modes, but a single one, are canceled.Such a steady-state solution is found to be stable with respect to small perturbations.

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Section: Simplified Model -No Spatial-hole Buring Effectsupporting

confidence: 75%

Section: Introductionmentioning

confidence: 64%

Elimination of Chaos in Multimode, Intracavity-Doubled Lasers in the Presence of Spatial Hole-Burning

Pietrzyk

Danailov

2001

Int. J. Bifurcation Chaos

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“…When the pump-modulation frequency is far from 2 1 (not 2 ) the response is linear in the sense that the laser is tied to the pump modulation and displays inphased P1 solutions. The nonlinear response is observed near 2 1 . Within the range limited by the points labelled 1 and 2, the lasers oscillate at half the modulation frequency (i.e.…”

Section: Medium-amplitude Pump Modulationmentioning

confidence: 92%

“…In a recent paper [1], we analysed numerically the response of a multimode laser, with intracavity second harmonic generation (ISHG), to a periodic modulation of the gain in the linear and nonlinear regimes. We found that, depending on the relative phase of the modal gain modulation, the resonance which is expected at the relaxation oscillation frequency can appear to be or can be shifted to the lower internal frequency.…”

mentioning

confidence: 99%

“…We note that 2 / 1 ∼ = 1 + γ , which means that the system has a single relaxation frequency if the coupling coefficient γ → 0. Along the lines of the analysis made in [5], one can prove analytically that the N modes relax to the steady state in phase at 2 and in antiphase at 1 . In the following sections, we set N = 3 and choose to vary the modulation frequency .…”

mentioning

confidence: 99%

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Antiphased modulation of a laser array

Wang

Mandel

Otsuka

1996

Quantum Semiclass. Opt.

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Abstract. We propose a model for globally coupled lasers with intracavity second harmonic generation in which each laser gain is modulated separately. Suitable selection of the modulation phases can shift the resonance expected at the relaxation oscillation towards lower frequencies. This shift is accompanied by a reduction of the resonance width.In a recent paper [1], we analysed numerically the response of a multimode laser, with intracavity second harmonic generation (ISHG), to a periodic modulation of the gain in the linear and nonlinear regimes. We found that, depending on the relative phase of the modal gain modulation, the resonance which is expected at the relaxation oscillation frequency can appear to be or can be shifted to the lower internal frequency. However, the possibility of modulating the gain coefficient of each mode separately seems remote at this point. In this paper, we propose a globally coupled solid-state laser array with intracavity second harmonic generation in which such control is possible. The proposed laser array consists of a bulk laser crystal and a second harmonic generation crystal placed within the cavity mirrors. The bulk crystal is pumped by multiple parallel beams through one of the cavity mirrors and each lasing element forms an element of the array. Diffractive global coupling between all lasing elements can be achieved by the other cavity mirror which is a feedback mirror, onto which the doubling crystal is attached, using the Talbot effect for spatial arrays [2]. In the case of the usual ISHG scheme in multimode lasers, the pump power is applied to all lasing modes identically. Therefore, it is very difficult or even almost impossible to control the small signal gain of each mode independently. In contrast, in the scheme of laser arrays that we propose, each element is pumped by a different beam. As a result, it is now possible to control each pump power independently. In the scheme of the globally coupled ISHG lasers that we propose, the gain of each element is shared by the lasing fields from other elements by a Talbot diffractive coupling. Therefore, a small amount of crossgain appears in addition to cross-saturation. For the usual ISHG in multimode lasers, mode coupling occurs due to spatial hole burning. In this case, different lasing fields with different frequencies interact with population inversion gratings corresponding to different standingwave patterns in the crystal and stimulated emission follows accordingly. Therefore, no cross-gain appears in this situation. Hence the model can be described by the following rate equations:

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Antiphase dynamics: a generalized reference model

Mandel

1997

Optics Communications

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Antiphase dynamics in pump-modulated multimode intracavity second-harmonic generation

Cited by 6 publications

References 18 publications

Elimination of Chaos in Multimode, Intracavity-Doubled Lasers in the Presence of Spatial Hole-Burning

Elimination of Chaos in Multimode, Intracavity-Doubled Lasers in the Presence of Spatial Hole-Burning

Antiphased modulation of a laser array

Antiphase dynamics: a generalized reference model

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