An Ultrasensitive Silicon Photonic Ion Sensor Enabled by 2D Plasmonic Molybdenum Oxide |
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| Authors: | Guanghui Ren Bao Yue Zhang Qifeng Yao Ali Zavabeti Cesar S Huertas Robert Brklja
a Muhammad Waqas Khan Hussein Nili Robi S Datta Hareem Khan Azmira Jannat Sumeet Walia Farjana Haque Luke A O'Dell Yichao Wang Lianqing Zhu Arnan Mitchell Jian Zhen Ou |
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| Affiliation: | Guanghui Ren,Bao Yue Zhang,Qifeng Yao,Ali Zavabeti,Cesar S. Huertas,Robert Brklja?a,Muhammad Waqas Khan,Hussein Nili,Robi S. Datta,Hareem Khan,Azmira Jannat,Sumeet Walia,Farjana Haque,Luke A. O'Dell,Yichao Wang,Lianqing Zhu,Arnan Mitchell,Jian Zhen Ou |
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| Abstract: | Silicon photonics has demonstrated great potential in ultrasensitive biochemical sensing. However, it is challenging for such sensors to detect small ions which are also of great importance in many biochemical processes. A silicon photonic ion sensor enabled by an ionic dopant–driven plasmonic material is introduced here. The sensor consists of a microring resonator (MRR) coupled with a 2D restacked layer of near‐infrared plasmonic molybdenum oxide. When the 2D plasmonic layer interacts with ions from the environment, a strong change in the refractive index results in a shift in the MRR resonance wavelength and simultaneously the alteration of plasmonic absorption leads to the modulation of MRR transmission power, hence generating dual sensing outputs which is unique to other optical ion sensors. Proof‐of‐concept via a pH sensing model is demonstrated, showing up to 7 orders improvement in sensitivity per unit area across the range from 1 to 13 compared to those of other optical pH sensors. This platform offers the unique potential for ultrasensitive and robust measurement of changes in ionic environment, generating new modalities for on‐chip chemical sensors in the micro/nanoscale. |
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| Keywords: | 2D materials doped semiconductors integrated optics ion sensors silicon photonics |
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