Design, Fabrication and Validation of Mixed Order Distributed Feed-Back Organic Diode Laser Cavity

Amani Ouirimi; Alex Chamberlain Chime; Nixson Loganathan; Mahmoud Chakaroun; Daan Lenstra; Alexis P.A. Fischer

doi:10.3390/photonics10060670

Design, Fabrication and Validation of Mixed Order Distributed Feed-Back Organic Diode Laser Cavity

Amani Ouirimi (Corresponding author), Alex Chamberlain Chime, Nixson Loganathan, Mahmoud Chakaroun, Daan Lenstra, Alexis P.A. Fischer

Photonic Integration

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Abstract

In the context of the quest for the organic laser diode, we address a key challenge to design and fabricate high-quality factor cavities compatible with electrical excitation of organic semiconductors. More precisely, we present the design of DFB micro-cavities for integration in organic laser diodes and their validation under optical pumping. To design high-quality factor mixed-order DFB micro-cavities, we consider the half- and quarter-wavelength multilayered system and use the optical waveguide analysis to quantify the effective indices of the high and low indices, and the matrix transfer method to calculate the reflectances. Matrices of DFB micro-cavities made from different doses and different grating periods were fabricated. We then identified those showing laser emission under optical pumping as an indication of optimal matching of their resonance wavelength with respect to the electroluminescence peak of the organic gain material. Potential applications of organic laser diodes deal with light communication, spectroscopy, sensors, and other applications where heterogenous integration is important.

Original language	English
Article number	670
Number of pages	23
Journal	Photonics
Volume	10
Issue number	6
DOIs	https://doi.org/10.3390/photonics10060670
Publication status	Published - Jun 2023

Bibliographical note

Funding Information:
This work was supported by the French Agence Nationale de la Recherche through the Program 453 Investissement d’Avenir under Grant ANR-11-IDEX-0005-02, by the Labex SEAM: Science Engineering and 454 Advanced Materials. This study was also supported by the IdEx Université de Paris, ANR-18-IDEX-0001. Additionally, the funding for this study was provided by the Dutch Research Council, Research Project Zwaartekracht.

Funding

This work was supported by the French Agence Nationale de la Recherche through the Program 453 Investissement d’Avenir under Grant ANR-11-IDEX-0005-02, by the Labex SEAM: Science Engineering and 454 Advanced Materials. This study was also supported by the IdEx Université de Paris, ANR-18-IDEX-0001. Additionally, the funding for this study was provided by the Dutch Research Council, Research Project Zwaartekracht.

Keywords

DFB cavities
OLED
optoelectronics
organic laser diode
photonic

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abstract = "In the context of the quest for the organic laser diode, we address a key challenge to design and fabricate high-quality factor cavities compatible with electrical excitation of organic semiconductors. More precisely, we present the design of DFB micro-cavities for integration in organic laser diodes and their validation under optical pumping. To design high-quality factor mixed-order DFB micro-cavities, we consider the half- and quarter-wavelength multilayered system and use the optical waveguide analysis to quantify the effective indices of the high and low indices, and the matrix transfer method to calculate the reflectances. Matrices of DFB micro-cavities made from different doses and different grating periods were fabricated. We then identified those showing laser emission under optical pumping as an indication of optimal matching of their resonance wavelength with respect to the electroluminescence peak of the organic gain material. Potential applications of organic laser diodes deal with light communication, spectroscopy, sensors, and other applications where heterogenous integration is important.",

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N2 - In the context of the quest for the organic laser diode, we address a key challenge to design and fabricate high-quality factor cavities compatible with electrical excitation of organic semiconductors. More precisely, we present the design of DFB micro-cavities for integration in organic laser diodes and their validation under optical pumping. To design high-quality factor mixed-order DFB micro-cavities, we consider the half- and quarter-wavelength multilayered system and use the optical waveguide analysis to quantify the effective indices of the high and low indices, and the matrix transfer method to calculate the reflectances. Matrices of DFB micro-cavities made from different doses and different grating periods were fabricated. We then identified those showing laser emission under optical pumping as an indication of optimal matching of their resonance wavelength with respect to the electroluminescence peak of the organic gain material. Potential applications of organic laser diodes deal with light communication, spectroscopy, sensors, and other applications where heterogenous integration is important.

AB - In the context of the quest for the organic laser diode, we address a key challenge to design and fabricate high-quality factor cavities compatible with electrical excitation of organic semiconductors. More precisely, we present the design of DFB micro-cavities for integration in organic laser diodes and their validation under optical pumping. To design high-quality factor mixed-order DFB micro-cavities, we consider the half- and quarter-wavelength multilayered system and use the optical waveguide analysis to quantify the effective indices of the high and low indices, and the matrix transfer method to calculate the reflectances. Matrices of DFB micro-cavities made from different doses and different grating periods were fabricated. We then identified those showing laser emission under optical pumping as an indication of optimal matching of their resonance wavelength with respect to the electroluminescence peak of the organic gain material. Potential applications of organic laser diodes deal with light communication, spectroscopy, sensors, and other applications where heterogenous integration is important.

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Design, Fabrication and Validation of Mixed Order Distributed Feed-Back Organic Diode Laser Cavity

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