Topological sensor on a silicon chip
An ultrasensitive photonic sensor is vital for sensing matter with absolute specificity. High specificity terahertz photonic sensors are essential in many fields, including medical research, clinical diagnosis, security inspection, and probing molecular vibrations in all forms of matter. Widespread...
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sg-ntu-dr.10356-1600232023-03-27T05:25:31Z Topological sensor on a silicon chip Kumar, Abhishek Gupta, Manoj Pitchappa, Prakash Tan, Yi Ji Wang, Nan Singh, Ranjan School of Physical and Mathematical Sciences Agency for Science, Technology and Research Centre for Disruptive Photonic Technologies (CDPT) The Photonics Institute Science::Physics::Optics and light Topological Sensor Ultra-High Q Topological Cavity Topological Photonics Terahertz Sensor An ultrasensitive photonic sensor is vital for sensing matter with absolute specificity. High specificity terahertz photonic sensors are essential in many fields, including medical research, clinical diagnosis, security inspection, and probing molecular vibrations in all forms of matter. Widespread photonic sensing technology detects small frequency shifts due to the targeted specimen, thus requiring ultra-high quality (Q) factor resonance. However, the existing terahertz waveguide resonating structures are prone to defects, possess limited Q-factor, and lack the feature of chip-scale CMOS integration. Here, inspired by the topologically protected edge state of light, we demonstrate a silicon valley photonic crystal based ultrasensitive, robust on-chip terahertz topological insulator sensor that consists of a topological waveguide critically coupled to a topological cavity with an ultra-high quality (Q) factor of =0.14×106. Topologically protected cavity resonance exhibits strong resilience against disorder and multiple sharp bends. Leveraging on the extremely narrow linewidth (2.3 MHz) of topological cavity resonance, the terahertz sensor shows a record-high figure of merit of 4000 RIU mm−1. In addition to the spectral shift, the intensity modulation of cavity resonance offers an additional sensor metric through active tuning of critical coupling in the waveguide-cavity system. We envision that the ultra-high Q photonic terahertz topological sensor could have chip-scale biomedical applications such as differentiation between normal and cancerous tissues by monitoring the water content. National Research Foundation (NRF) Published version All the authors acknowledge the research funding support from the National Research Foundation (NRF) Singapore (Grant No. NRF-CRP-2019-0005). 2022-07-12T03:01:26Z 2022-07-12T03:01:26Z 2022 Journal Article Kumar, A., Gupta, M., Pitchappa, P., Tan, Y. J., Wang, N. & Singh, R. (2022). Topological sensor on a silicon chip. Applied Physics Letters, 121(1), 011101-. https://dx.doi.org/10.1063/5.0097129 0003-6951 https://hdl.handle.net/10356/160023 10.1063/5.0097129 1 121 011101 en NRF-CRP-2019-0005 Applied Physics Letters 10.21979/N9/NDBWOX © 2022 Author(s). All rights reserved. This paper was published by AIP Publishing in Applied Physics Letters and is made available with permission of Author(s). application/pdf |
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Science::Physics::Optics and light Topological Sensor Ultra-High Q Topological Cavity Topological Photonics Terahertz Sensor |
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Science::Physics::Optics and light Topological Sensor Ultra-High Q Topological Cavity Topological Photonics Terahertz Sensor Kumar, Abhishek Gupta, Manoj Pitchappa, Prakash Tan, Yi Ji Wang, Nan Singh, Ranjan Topological sensor on a silicon chip |
| description |
An ultrasensitive photonic sensor is vital for sensing matter with absolute specificity. High specificity terahertz photonic sensors are essential in many fields, including medical research, clinical diagnosis, security inspection, and probing molecular vibrations in all forms of matter. Widespread photonic sensing technology detects small frequency shifts due to the targeted specimen, thus requiring ultra-high quality (Q) factor resonance. However, the existing terahertz waveguide resonating structures are prone to defects, possess limited Q-factor, and lack the feature of chip-scale CMOS integration. Here, inspired by the topologically protected edge state of light, we demonstrate a silicon valley photonic crystal based ultrasensitive, robust on-chip terahertz topological insulator sensor that consists of a topological waveguide critically coupled to a topological cavity with an ultra-high quality (Q) factor of =0.14×106. Topologically protected cavity resonance exhibits strong resilience against disorder and multiple sharp bends. Leveraging on the extremely narrow linewidth (2.3 MHz) of topological cavity resonance, the terahertz sensor shows a record-high figure of merit of 4000 RIU mm−1. In addition to the spectral shift, the intensity modulation of cavity resonance offers an additional sensor metric through active tuning of critical coupling in the waveguide-cavity system. We envision that the ultra-high Q photonic terahertz topological sensor could have chip-scale biomedical applications such as differentiation between normal and cancerous tissues by monitoring the water content. |
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School of Physical and Mathematical Sciences |
| author_facet |
School of Physical and Mathematical Sciences Kumar, Abhishek Gupta, Manoj Pitchappa, Prakash Tan, Yi Ji Wang, Nan Singh, Ranjan |
| format |
Article |
| author |
Kumar, Abhishek Gupta, Manoj Pitchappa, Prakash Tan, Yi Ji Wang, Nan Singh, Ranjan |
| author_sort |
Kumar, Abhishek |
| title |
Topological sensor on a silicon chip |
| title_short |
Topological sensor on a silicon chip |
| title_full |
Topological sensor on a silicon chip |
| title_fullStr |
Topological sensor on a silicon chip |
| title_full_unstemmed |
Topological sensor on a silicon chip |
| title_sort |
topological sensor on a silicon chip |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/160023 |
| _version_ |
1761781413071290368 |