Room-temperature continuous-wave metal grating distributed feedback quantum cascade lasers

Carras, Mathieu; Maisons, G.; Simozrag, B.; Garcia, M.; Parillaud, O.; Massies, J.; Marcadet, X.

doi:10.1063/1.3399779

Cited by 64 publications

(36 citation statements)

References 12 publications

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“…Another spectral measurement to deduce thermal resistance is illustrated in Ref. [18]. The difference in wavelength comes from the thermal resistance of the device Dv ¼ ðv=nÞðdn=dTÞDT, where Dm is the frequency difference, DT is the temperature difference and n is the optical index.…”

Section: Lasers Characterizationmentioning

confidence: 99%

Stable single mode operation of quantum cascade lasers by complex-coupled second-order distributed feedback grating

Liu

Zhang

Jia

et al. 2015

Solid-State Electronics

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Section: Lasers Characterizationmentioning

confidence: 99%

Stable single mode operation of quantum cascade lasers by complex-coupled second-order distributed feedback grating

Liu

Zhang

Jia

et al. 2015

Solid-State Electronics

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“…Une nouvelle approche basée sur l'utilisation de réseaux métalliques de surface a été développée. Cette nouvelle approche repose sur une modulation de l'indice générée par le couplage entre les modes guidés dans la zone active et un mode confiné à l'interface, entre le métal et le guide supérieur (figures 4 et 5) [6]. Précisons que ce couplage est possible car les modes contra-propagatifs d'une part, et le mode de surface d'autre part, ont la même polarisation TM.…”

Section: Fonctionnement Mono-fréquenceunclassified

“…Un avantage supplé-mentaire de cette approche est sa robustesse vis-à-vis des variations technologiques, ce qui permet de contrôler la longueur d'onde d'émission à plus ou moins 1 cm -1 . Des QCL DFB fonctionnant en mode pulsé ou continu sont maintenant disponibles commercialement (fi gure 6, voir aussi les fiches techniques sur www.3-5lab.fr) sur la totalité de la plage allant de 4 à 10 μm [6]. Les lasers fonctionnent à température ambiante sur un module thermoélectrique à effet Peltier.…”

Section: Fonctionnement Mono-fréquenceunclassified

Les lasers à cascade quantique : l’accès au moyen infrarouge

Marcadet¹,

Carras²,

Maisons³

et al. 2011

Photoniques

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“…In order to reduce the losses introduced by the metal, and thus increase the operating temperature, the proposed configuration is based on the analysis reported in a previous paper, enabling the engineering of low loss-index coupled DFB with metal gratings [2][3]. The DFB cavity has typical dimensions (about 2mm x30µm) whereas the coupler section is larger to ensure a reduction of the divergence but should be shorter to avoid losses Fig.…”

mentioning

confidence: 99%

“…For such type of application, single-mode lasers with narrow line-width are necessary and therefore distributed feedback (DFB) QCLs have been recently developed [1][2][3][4]. In standard approach, light is emitted by a cleaved facet.…”

mentioning

confidence: 99%

Directional single mode QCL emission using metal grating second order coupler at room temperature

Maisons

Carras

Garcia

et al. 2010

22nd IEEE International Semiconductor Laser Conference

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Low beam divergence (2.1°*4°) substrate emission from a quantum cascade laser is demonstrated with top metal grating at room temperature. An index coupled, distributed feedback laser with a SMSR of 30dB is coupled to a monolithic extraction area.Surface emission, quantum cascade laser, top metal grating, low divergence.In the last decade, strong efforts have been devoted to the development of quantum cascade lasers (QCLs) emitting in the medium infra-red region (MIR), motivated in particular by the need to improve the performances of trace-gas analysis systems. For such type of application, single-mode lasers with narrow line-width are necessary and therefore distributed feedback (DFB) QCLs have been recently developed [1][2][3][4]. In standard approach, light is emitted by a cleaved facet. To ensure that the laser is spatially single-mode, the section of the waveguide is reduced to about one wavelength. Thereby, emission from the edge of a DFB QCL is highly divergent. For this reason, lenses are required for applications such as gas sensing. The demonstration of substrate emission at room temperature with improved divergence has already been achieved in the case of a ridge waveguide configuration with a bi-periodic grating [5]. In such structure, the size of the waveguide in the direction perpendicular to the grating could not be higher than in the case of a classical QCL cavity (about 10µm in the mid-IR) in order to suppress higher order transverse modes. We have demonstrated that a combination of a classical DFB QCL, with a first order grating ( eff DFB n 2 0 λ = Λ ), and a monolithic coupler, with a second order grating ( eff c n 0 λ = Λ), allows us to design a singlemode QCL with a low beam divergence and with a Gaussian like profile in the two directions. Preliminary results obtained on InGaAs/AlInAs DFB QCLs made following this approach and emitting at 5.65µm at room temperature with a low beam divergence are reported.In order to reduce the losses introduced by the metal, and thus increase the operating temperature, the proposed configuration is based on the analysis reported in a previous paper, enabling the engineering of low loss-index coupled DFB with metal gratings [2][3]. The DFB cavity has typical dimensions (about 2mm x30µm) whereas the coupler section is larger to ensure a reduction of the divergence but should be shorter to avoid losses Fig. 1.The Fig. 2 presents a typical mono-lobe far field obtained for such structure with L E =300µm and l E =30µm. The mono-lobe far field pattern has a very low divergence in the two directions. The Full Width at Half a Maximum is only 2.1°*4°. This structure is mono-mode, Fig. 3, and exhibits a Side Mode Suppression Ratio of 30dB.

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Room-temperature continuous-wave metal grating distributed feedback quantum cascade lasers

Cited by 64 publications

References 12 publications

Stable single mode operation of quantum cascade lasers by complex-coupled second-order distributed feedback grating

Stable single mode operation of quantum cascade lasers by complex-coupled second-order distributed feedback grating

Les lasers à cascade quantique : l’accès au moyen infrarouge

Directional single mode QCL emission using metal grating second order coupler at room temperature

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