AI Article Synopsis
- - A new analyzer called the multi-mechanism collaboration enhancement photoacoustic spectroscopy analyzer (MCEPA) is developed for highly sensitive real-time detection of hydrogen sulfide (HS) in sulfur fluoride (SF) environments, using multiple enhancement techniques.
- - The system utilizes a photoacoustic cell (PAC) for acoustic resonance enhancement, a specialized fiber-optic acoustic sensor that leverages cantilever enhancements, and improved light power from an erbium-doped fiber amplifier (EDFA) to boost photoacoustic signals.
- - Experimental results reveal that the optimized MCEPA can detect HS at extremely low concentrations (10.96 ppb) in SF backgrounds with excellent sensitivity and is resistant to interference from electromagnetic signals. *
Article Abstract
To realize the real-time highly sensitive detection of SF decomposition product HS, a multi-mechanism collaboration enhancement photoacoustic spectroscopy analyzer (MCEPA) based on acoustic resonance enhancement, cantilever enhancement and excitation light enhancement is proposed. An SF background gas-induced photoacoustic cell (PAC) was used for acoustic resonance (AR) enhancement of the photoacoustic signals. A fiber-optic acoustic sensor based on a silicon cantilever is optimized and fabricated. The narrow-band acoustic signal enhancement based on cantilever mechanical resonance (MR) is realized in the optimal working frequency band of the PAC. A fiber-coupled DFB cascaded an Erbium-doped fiber amplifier (EDFA) realized the light power enhancement (LPE) of the photoacoustic signals excitation source. Experimental results show that the MR of the fiber-optic silicon cantilever acoustic sensor (FSCAS) is matched with the AR of the PAC and combined with the LPE, which realizes the multi-mechanism collaboration enhancement of weak photoacoustic signals. The Allan-Werle deviation evaluation showed that the minimum detection limit of HS in the SF background is 10.96 ppb when the average time is 200 s. Benefiting from the all-optimization of photoacoustic excitation and detection, the MCEPA has near-field high-sensitivity gas detection capability immune to electromagnetic interference.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9841283 | PMC |
| http://dx.doi.org/10.1016/j.pacs.2023.100449 | DOI Listing |
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