4.7 Article

Microwave Gas Sensor Based on Graphene Aerogels

期刊

IEEE SENSORS JOURNAL
卷 23, 期 17, 页码 19282-19289

出版社

IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/JSEN.2023.3295176

关键词

Sensors; Graphene; Gas detectors; Surface waves; Microwave theory and techniques; Conductivity; Resonators; Gas sensor; graphene; graphene aerogel (GA); microwave

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This article presents an experimental demonstration of a novel microwave gas sensor based on graphene aerogel (GA). The sensor utilizes the porous structure of GA and the modulation of graphene conductivity to detect gases in the air. The results show that the sensor exhibits clear shifts in the scattering parameters of the waveguide upon exposure to different gases, and it also demonstrates excellent reproducibility when exposed to alternating cycles of air and vacuum. These findings open up possibilities for the development of new gas sensors for applications such as breath analysis.
In this article, the experimental demonstration of a novel microwave gas sensor based on graphene aerogel (GA) is presented. This device makes use of a highly porous structure of the aerogel in combination with the modulation of graphene AC conductivity upon exposure to vacuum and ambient air. As a proof of concept, we integrate the GA into rectangular waveguides and measure its scattering parameters with a vector network analyzer (VNA). The aerogel is characterized by a combination of scanning electron microscopy (SEM) and four-probe DC measurements. The aerogel is integrated into WR-90 waveguides by customdesigned support and wave propagation is tested over the 812 GHz frequency range (X-band). By exposing the aerogel to either air or a moderate vacuum, clear shifts in the waveguide scattering parameters are observed. In particular, changes of approximate to 3 and approximate to 1 dB in the transmission and reflection parameters of the waveguide are obtained, respectively. Moreover, the sensor exhibits excellent reproducibility when exposed to alternating cycles of air and vacuum, proving that the shifts in microwave transmission and reflection are caused by changes in the conductivity of the GA due to the absorption and desorption of gas molecules. These proof-of-concept results pave the way for the development of a new class of gas sensors for applications such as breath analysis.

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