Mid-infrared, ultra-broadband, low-loss, compact arbitrary power splitter based on adiabatic mode evolution
We designed and demonstrated TE-mode arbitrary power splitters based on adiabatic mode evolution. The power splitters are designed with a footprint of smaller than 12 × 2.9 μm 2 , fabricated on a 400-nm silicon-on-insulator platform, requiring only a single etch step. The optimization process and th...
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sg-ntu-dr.10356-1435632020-09-09T06:12:37Z Mid-infrared, ultra-broadband, low-loss, compact arbitrary power splitter based on adiabatic mode evolution Sia, Brian Jia Xu Wang, Wanjun Guo, Xin Zhou, Jin Zhang, Zecen Mohamed Said Rouifed Li, Xiang Qiao, Zhong Liang Liu, Chong Yang Littlejohns, Callum Reed, Graham T. Wang, Hong School of Electrical and Electronic Engineering Novitas, Silicon Centre of Excellence Engineering::Electrical and electronic engineering Waveguides Mid Infrared We designed and demonstrated TE-mode arbitrary power splitters based on adiabatic mode evolution. The power splitters are designed with a footprint of smaller than 12 × 2.9 μm 2 , fabricated on a 400-nm silicon-on-insulator platform, requiring only a single etch step. The optimization process and the conditions for arbitrary-power splitting are performed using three-dimensional-FDTD simulations. We prove this concept through the fabrication of asymmetrical adiabatic evolution-based power splitters with splitting ratios of 50:50, 60:40, and 70:30. The fabricated devices are shown to agree closely with simulation results. Broadband operation with low insertion loss of 0.11-0.6 dB is demonstrated across the 3.66-3.89 μm wavelength range (230 nm). This component has applications in a multitude of areas such as spectroscopic optical sensing and optical phased arrays photonic integrated circuits etc. Nanyang Technological University National Research Foundation (NRF) Published version This work was supported in part by the National Research Foundation Singapore under Grant NRF-CRP12-2013-04, and in part by the Nanyang Technological University-A∗Start Silicon Technologies Centre of Excellence. 2020-09-09T06:12:37Z 2020-09-09T06:12:37Z 2019 Journal Article Sia, B. J. X., Wang, W., Guo, X., Zhou, J., Zhang, Z., Mohamed Said Rouifed, . . . Wang, H. (2019). Mid-infrared, ultra-broadband, low-loss, compact arbitrary power splitter based on adiabatic mode evolution. IEEE Photonics Journal, 11(2),6601111-. doi:10.1109/JPHOT.2019.2907788 1943-0655 https://hdl.handle.net/10356/143563 10.1109/JPHOT.2019.2907788 2 11 en NRF-CRP12-2013-04 IEEE Photonics Journal © 2019 IEEE. This journal is 100% open access, which means that all content is freely available without charge to users or their institutions. Articles accepted before 12 June 2019 were published under a CC BY 3.0 or the IEEE Open Access Publishing Agreement license. Questions about copyright policies or reuse rights may be directed to the IEEE Intellectual Property Rights Office at +1-732-562-3966 or copyrights@ieee.org. application/pdf |
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Engineering::Electrical and electronic engineering Waveguides Mid Infrared |
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Engineering::Electrical and electronic engineering Waveguides Mid Infrared Sia, Brian Jia Xu Wang, Wanjun Guo, Xin Zhou, Jin Zhang, Zecen Mohamed Said Rouifed Li, Xiang Qiao, Zhong Liang Liu, Chong Yang Littlejohns, Callum Reed, Graham T. Wang, Hong Mid-infrared, ultra-broadband, low-loss, compact arbitrary power splitter based on adiabatic mode evolution |
| description |
We designed and demonstrated TE-mode arbitrary power splitters based on adiabatic mode evolution. The power splitters are designed with a footprint of smaller than 12 × 2.9 μm 2 , fabricated on a 400-nm silicon-on-insulator platform, requiring only a single etch step. The optimization process and the conditions for arbitrary-power splitting are performed using three-dimensional-FDTD simulations. We prove this concept through the fabrication of asymmetrical adiabatic evolution-based power splitters with splitting ratios of 50:50, 60:40, and 70:30. The fabricated devices are shown to agree closely with simulation results. Broadband operation with low insertion loss of 0.11-0.6 dB is demonstrated across the 3.66-3.89 μm wavelength range (230 nm). This component has applications in a multitude of areas such as spectroscopic optical sensing and optical phased arrays photonic integrated circuits etc. |
| author2 |
School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Sia, Brian Jia Xu Wang, Wanjun Guo, Xin Zhou, Jin Zhang, Zecen Mohamed Said Rouifed Li, Xiang Qiao, Zhong Liang Liu, Chong Yang Littlejohns, Callum Reed, Graham T. Wang, Hong |
| format |
Article |
| author |
Sia, Brian Jia Xu Wang, Wanjun Guo, Xin Zhou, Jin Zhang, Zecen Mohamed Said Rouifed Li, Xiang Qiao, Zhong Liang Liu, Chong Yang Littlejohns, Callum Reed, Graham T. Wang, Hong |
| author_sort |
Sia, Brian Jia Xu |
| title |
Mid-infrared, ultra-broadband, low-loss, compact arbitrary power splitter based on adiabatic mode evolution |
| title_short |
Mid-infrared, ultra-broadband, low-loss, compact arbitrary power splitter based on adiabatic mode evolution |
| title_full |
Mid-infrared, ultra-broadband, low-loss, compact arbitrary power splitter based on adiabatic mode evolution |
| title_fullStr |
Mid-infrared, ultra-broadband, low-loss, compact arbitrary power splitter based on adiabatic mode evolution |
| title_full_unstemmed |
Mid-infrared, ultra-broadband, low-loss, compact arbitrary power splitter based on adiabatic mode evolution |
| title_sort |
mid-infrared, ultra-broadband, low-loss, compact arbitrary power splitter based on adiabatic mode evolution |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/143563 |
| _version_ |
1681059183741370368 |