Compact and Highly Sensitive NO2 Photoacoustic Sensor for Environmental Monitoring

Pan, Yufeng; Dong, Lei; Yin, Xukun; Wu, Hongpeng

doi:10.3390/molecules25051201

Cited by 37 publications

(19 citation statements)

References 25 publications

(39 reference statements)

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“…However, some specificity of the signal formation should be considered to distinguish the optical properties of the considered media with good precision. A typical application of PA spectroscopy is the detection of atmospheric CH 4 , CO 2 [107] ppm, NO 2 [108], and N 2 O, and sensitivity in the range of a few parts per billion could be achieved [109]. For further insight regarding PA gas sensing, one can refer to the recent reviews [2,105,106].…”

Section: Solid-and Liquid-phase Photoacoustic Ft-ir Spectroscopymentioning

confidence: 99%

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Application of the Photoacoustic Approach in the Characterization of Nanostructured Materials

et al. 2022

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A new generation of sensors can be engineered based on the sensing of several markers to satisfy the conditions of the multimodal detection principle. From this point of view, photoacoustic-based sensing approaches are essential. The photoacoustic effect relies on the generation of light-induced deformation (pressure) perturbations in media, which is essential for sensing applications since the photoacoustic response is formed due to a contrast in the optical, thermal, and acoustical properties. It is also particularly important to mention that photoacoustic light-based approaches are flexible enough for the measurement of thermal/elastic parameters. Moreover, the photoacoustic approach can be used for imaging and visualization in material research and biomedical applications. The advantages of photoacoustic devices are their compact sizes and the possibility of on-site measurements, enabling the online monitoring of material parameters. The latter has significance for the development of various sensing applications, including biomedical ones, such as monitoring of the biodistribution of biomolecules. To extend sensing abilities and to find reliable measurement conditions, one needs to clearly understand all the phenomena taking place during energy transformation during photoacoustic signal formation. Therefore, the current paper is devoted to an overview of the main measurement principles used in the photoacoustic setup configurations, with a special focus on the key physical parameters.

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Section: Solid-and Liquid-phase Photoacoustic Ft-ir Spectroscopymentioning

confidence: 99%

“…A typical application of PA spectroscopy is the detection of atmospheric CH4, CO [107] ppm, NO2 [108], and N2O, and sensitivity in the range of a few parts per billion coul be achieved [109]. For further insight regarding PA gas sensing, one can refer to the recen reviews [2,105,106].…”

Section: Solid-and Liquid-phase Photoacoustic Ft-ir Spectroscopymentioning

confidence: 99%

Application of the Photoacoustic Approach in the Characterization of Nanostructured Materials

et al. 2022

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“…Nitrogen Dioxide (NO 2 ) LD [108][109][110][111][112] Multimode LD [113] LED [114][115][116][117][118] Nitric Oxide (N 2 O) QCL [112,119] OPO [120] Nitrogen oxide (NO) QCL [121] LD [122] Ammonia (NH 3 ) QCL [123][124][125] CO 2 laser [126,127] LD [128] Carbon Dioxide (CO 2 ) QCL [129] CO 2 laser [130] LD [131][132][133][134] OPO [135] Table 2. Cont.…”

Section: Target Gas (Es) Light Source Referencementioning

confidence: 99%

Photoacoustic-Based Gas Sensing: A Review

Palzer

2020

Sensors

102

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The use of the photoacoustic effect to gauge the concentration of gases is an attractive alternative in the realm of optical detection methods. Even though the effect has been applied for gas sensing for almost a century, its potential for ultra-sensitive and miniaturized devices is still not fully explored. This review article revisits two fundamentally different setups commonly used to build photoacoustic-based gas sensors and presents some distinguished results in terms of sensitivity, ultra-low detection limits, and miniaturization. The review contrasts the two setups in terms of the respective possibilities to tune the selectivity, sensitivity, and potential for miniaturization.

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“…Beyond conventional methods such as electro-chemistry and gas chromatography [5] , [6] , optical methods allow improved selectivity and sensitivity as well as fast response. Optical methods using laser absorption spectroscopy (LAS) based on the ‘finger-print’ absorption lines of molecules, such as tunable diode laser absorption spectroscopy (TDLAS), cavity ring-down spectroscopy (CRDS) and photoacoustic spectroscopy (PAS) [7] , [8] , [9] , [10] , have been widely investigated for trace gas detection. TDLAS-based sensors have been widely commercialized [11] , and it fundamentally relies on the long optical path and superior photodetectors to achieve favorable sensing performance.…”

Section: Introductionmentioning

confidence: 99%

Ultra-sensitive ppb-level methane detection based on NIR all-optical photoacoustic spectroscopy by using differential fiber-optic microphones with gold-chromium composite nanomembrane

et al. 2022

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Compact and Highly Sensitive NO2 Photoacoustic Sensor for Environmental Monitoring

Cited by 37 publications

References 25 publications

Application of the Photoacoustic Approach in the Characterization of Nanostructured Materials

Application of the Photoacoustic Approach in the Characterization of Nanostructured Materials

Photoacoustic-Based Gas Sensing: A Review

Ultra-sensitive ppb-level methane detection based on NIR all-optical photoacoustic spectroscopy by using differential fiber-optic microphones with gold-chromium composite nanomembrane

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