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Autori principali: Zhuang, Ruobin, He, Jianfeng, Zheng, Huadan
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2412.18822
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author Zhuang, Ruobin
He, Jianfeng
Zheng, Huadan
author_facet Zhuang, Ruobin
He, Jianfeng
Zheng, Huadan
contents Ensuring safety and efficiency in emerging hydrogen-hydrocarbon fuel systems requires accurate measurement of multiple gas components in real time. However, existing detection techniques generally lack the capability to quantitatively measure hydrogen and natural gas constituents simultaneously. Here, we present a novel conductance-photoacoustic spectroscopy (CPAS) method that integrates platinum-modified conductance measurements with beat-frequency photoacoustic detection. By bridging a quartz tuning fork with a platinum microwire, our approach enables direct monitoring of hydrogen concentration via frequency modulation, while simultaneously capturing propane's photoacoustic signal with a single detection channel. Experimental results confirm that the platinum microwire effectively fine-tunes the tuning fork's mechanical properties for high-sensitivity hydrogen measurement, and the beat-frequency photoacoustic signals from propane absorption reveal complementary hydrocarbon concentration information. This unified sensor design is inherently compact, rapid, and calibration-free, making it particularly suitable for applications that demand real-time multiparameter gas analysis, including industrial process control and environmental monitoring. Taken together, these findings demonstrate that combining conductance and photoacoustic spectroscopies into a single integrated platform significantly advances the state of multi-component gas detection and holds promise for further enhancements in sensitivity and adaptability.
format Preprint
id arxiv_https___arxiv_org_abs_2412_18822
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Conductance-Photoacoustic Spectroscopy for OneSignal Measurement of Multi-components
Zhuang, Ruobin
He, Jianfeng
Zheng, Huadan
Optics
Ensuring safety and efficiency in emerging hydrogen-hydrocarbon fuel systems requires accurate measurement of multiple gas components in real time. However, existing detection techniques generally lack the capability to quantitatively measure hydrogen and natural gas constituents simultaneously. Here, we present a novel conductance-photoacoustic spectroscopy (CPAS) method that integrates platinum-modified conductance measurements with beat-frequency photoacoustic detection. By bridging a quartz tuning fork with a platinum microwire, our approach enables direct monitoring of hydrogen concentration via frequency modulation, while simultaneously capturing propane's photoacoustic signal with a single detection channel. Experimental results confirm that the platinum microwire effectively fine-tunes the tuning fork's mechanical properties for high-sensitivity hydrogen measurement, and the beat-frequency photoacoustic signals from propane absorption reveal complementary hydrocarbon concentration information. This unified sensor design is inherently compact, rapid, and calibration-free, making it particularly suitable for applications that demand real-time multiparameter gas analysis, including industrial process control and environmental monitoring. Taken together, these findings demonstrate that combining conductance and photoacoustic spectroscopies into a single integrated platform significantly advances the state of multi-component gas detection and holds promise for further enhancements in sensitivity and adaptability.
title Conductance-Photoacoustic Spectroscopy for OneSignal Measurement of Multi-components
topic Optics
url https://arxiv.org/abs/2412.18822