Cylindrical surfaces enable wavelength-selective extinction and sub-0.2 nm linewidth in 250 μm-gap silicon Fabry–Pérot cavities
In this paper, we propose two different designs of micromachined Fabry-Pérot optical cavities, with first motivation of improving the quality factor (Q -factor) and in the same time allowing increased cavity length L. Our approach consists of providing a solution to the main loss mechanism in conve...
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sg-ntu-dr.10356-997602020-03-07T14:00:31Z Cylindrical surfaces enable wavelength-selective extinction and sub-0.2 nm linewidth in 250 μm-gap silicon Fabry–Pérot cavities Malak, Maurine Marty, Frédéric Pavy, Nicolas Peter, Yves-Alain Liu, Ai Qun Bourouina, Tarik School of Electrical and Electronic Engineering DRNTU::Engineering::Electrical and electronic engineering In this paper, we propose two different designs of micromachined Fabry-Pérot optical cavities, with first motivation of improving the quality factor (Q -factor) and in the same time allowing increased cavity length L. Our approach consists of providing a solution to the main loss mechanism in conventional FP cavities related to the expansion of the Gaussian light beam after multiple reflections inside the cavity. The first design is based on all-silicon cylindrical Bragg mirrors, which provide 1-D confinement of light. In addition to wavelength selectivity, the first design also demonstrates its potential for a new class of applications, including wavelength selective extinction through mode-selective excitation, where the fiber-to-cavity distance is used as the control parameter. The second design is based on cylindrical Bragg mirrors combined with a fiber rod lens to provide a complete solution for 2-D confinement of light. This approach outperforms the first design in terms of Q-factor, of nearly 9000 for around 250 μm-long cavity, which suggests its potential use for biochemical sensing and analysis as well as cavity enhancement applications requiring high Q.L values. 2013-10-30T03:48:55Z 2019-12-06T20:11:07Z 2013-10-30T03:48:55Z 2019-12-06T20:11:07Z 2011 2011 Journal Article Malak, M., Marty, F., Pavy, N., Peter, Y. A., Liu, A.-Q., & Bourouina, T. (2012). Cylindrical Surfaces Enable Wavelength-Selective Extinction and Sub-0.2 nm Linewidth in 250 μm-Gap Silicon Fabry–Pérot Cavities. Journal of Microelectromechanical Systems, 21(1), 171-180. https://hdl.handle.net/10356/99760 http://hdl.handle.net/10220/17029 10.1109/JMEMS.2011.2174427 en Journal of microelectromechanical systems |
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DRNTU::Engineering::Electrical and electronic engineering Malak, Maurine Marty, Frédéric Pavy, Nicolas Peter, Yves-Alain Liu, Ai Qun Bourouina, Tarik Cylindrical surfaces enable wavelength-selective extinction and sub-0.2 nm linewidth in 250 μm-gap silicon Fabry–Pérot cavities |
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In this paper, we propose two different designs of micromachined Fabry-Pérot optical cavities, with first motivation of improving the quality factor (Q -factor) and in the same time allowing increased cavity length L. Our approach consists of providing a solution to the main loss mechanism in conventional FP cavities related to the expansion of the Gaussian light beam after multiple reflections inside the cavity. The first design is based on all-silicon cylindrical Bragg mirrors, which provide 1-D confinement of light. In addition to wavelength selectivity, the first design also demonstrates its potential for a new class of applications, including wavelength selective extinction through mode-selective excitation, where the fiber-to-cavity distance is used as the control parameter. The second design is based on cylindrical Bragg mirrors combined with a fiber rod lens to provide a complete solution for 2-D confinement of light. This approach outperforms the first design in terms of Q-factor, of nearly 9000 for around 250 μm-long cavity, which suggests its potential use for biochemical sensing and analysis as well as cavity enhancement applications requiring high Q.L values. |
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School of Electrical and Electronic Engineering |
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School of Electrical and Electronic Engineering Malak, Maurine Marty, Frédéric Pavy, Nicolas Peter, Yves-Alain Liu, Ai Qun Bourouina, Tarik |
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Article |
| author |
Malak, Maurine Marty, Frédéric Pavy, Nicolas Peter, Yves-Alain Liu, Ai Qun Bourouina, Tarik |
| author_sort |
Malak, Maurine |
| title |
Cylindrical surfaces enable wavelength-selective extinction and sub-0.2 nm linewidth in 250 μm-gap silicon Fabry–Pérot cavities |
| title_short |
Cylindrical surfaces enable wavelength-selective extinction and sub-0.2 nm linewidth in 250 μm-gap silicon Fabry–Pérot cavities |
| title_full |
Cylindrical surfaces enable wavelength-selective extinction and sub-0.2 nm linewidth in 250 μm-gap silicon Fabry–Pérot cavities |
| title_fullStr |
Cylindrical surfaces enable wavelength-selective extinction and sub-0.2 nm linewidth in 250 μm-gap silicon Fabry–Pérot cavities |
| title_full_unstemmed |
Cylindrical surfaces enable wavelength-selective extinction and sub-0.2 nm linewidth in 250 μm-gap silicon Fabry–Pérot cavities |
| title_sort |
cylindrical surfaces enable wavelength-selective extinction and sub-0.2 nm linewidth in 250 μm-gap silicon fabry–pérot cavities |
| publishDate |
2013 |
| url |
https://hdl.handle.net/10356/99760 http://hdl.handle.net/10220/17029 |
| _version_ |
1681049743892938752 |