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Ultracompact gas sensor with metal-organic-framework-based differential fiber-optic Fabry-Perot nanocavities

Hyun‐Tae Kim, Wonseok Hwang, Yun Liu, Miao Yu

2020Optics Express46 citationsDOIOpen Access PDF

Abstract

Refractive-index (RI)-based sensing is a major optical sensing modality that can be implemented in various spectral ranges. While it has been widely used for sensing of biochemical liquids, RI-based gas sensing, particularly small-molecule gases, is challenging due to the extremely small RI change induced by gas concentration variations. We propose a RI-based ultracompact fiber-optic differential gas sensor that employs metal-organic-framework (MOF)-based dual Fabry-Perot (FP) nanocavities. A MOF is used as the FP cavity material to enhance the sensitivity as well as the selectivity to particular gas molecules. The differential sensing scheme leverages the opposite change in the cavity-length-dependent reflection of the two FP cavities, which further enhances the sensitivity compared with single FP cavity based sensing. For proof-of-concept, a fiber-optic CO 2 sensor with ZIF-8-based dual FP nanocavities was fabricated. The effective footprint of the sensor was as small as 157 µm 2 and the sensor showed an enhanced sensitivity of 48.5 mV/CO 2 Vol%, a dynamic range of 0-100 CO 2 Vol%, and a resolution of 0.019 CO 2 Vol% with 1 Hz low-pass filtering. Although the current sensor was only demonstrated for CO 2 sensing, the proposed sensor concept can be used for sensing of a variety of gases when different kinds of MOFs are utilized.

Topics & Concepts

Fabry–Pérot interferometerOpticsMaterials scienceOptical fiberFiber optic sensorOptoelectronicsPhysicsWavelengthGas Sensing Nanomaterials and SensorsAdvanced Fiber Optic SensorsPorphyrin and Phthalocyanine Chemistry
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