Simple technique of coupling a diode laser into a linear power buildup cavity for Raman gas sensing

Ge, Heng; Kong, Weiping; Wang, Rui; Gang, Zhao; Ma, Weiguang; Chen, Weigen; Wan, Fu

doi:10.1364/ol.486417

Cited by 64 publications

(20 citation statements)

References 23 publications

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“…Second harmonic-wavelength modulation spectroscopy (2f -WMS) technology is utilized, which can effectively eliminate The high-frequency sine wave with frequency f 1 /2 generated by the lock-in amplifier is employed for wavelength modulation, and the low-frequency triangular wave is applied for spectrum scanning. 45 The excitation light enters the MDPAC after passing through a fiber-optic collimator (FOC). The MDPAC has the obvious advantage of reducing gas flow noise, which is the fundamental reason for realizing high-sensitivity dynamic detection of trace gases.…”

Section: Differential Lock-in Amplification Technology Ofmentioning

confidence: 99%

Fiber-Optic Photoacoustic CO Sensor for Gas Insulation Equipment Monitoring Based on Cantilever Differential Lock-In Amplification and Optical Excitation Enhancement

Zhao,

Ma,

Wang

et al. 2024

Anal. Chem.

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A fiber-optic photoacoustic CO sensor for gas insulation equipment is proposed, which relies on F−P interferometric cantilever-based differential lockin amplification and optical multipass excitation enhancement. The sensor has excellent characteristics of high sensitivity, antielectromagnetic interference, fast response, and long-distance detection. The photoacoustic pressure waves in the two resonators of the differential photoacoustic cell (DPAC) are simultaneously detected by two fiber-optic interferometric cantilevers and processed differentially; thereby, the gas flow noise is effectively suppressed. Based on the comprehensive analysis of the superposition of photoacoustic excitation and multipass absorption, the diameter of the resonator is determined to be 6 mm. The optical power emitted by the 1566.6 nm distributed feedback laser is increased to 500 mW by an erbium-doped fiber amplifier. The near-infrared light is reflected 30 times in the multipass cell, which improves the order of magnitude of optical effective excitation. Due to the low sound velocity of SF 6 gas, the resonant frequency of the DPAC with a resonator length of 80 mm is 760 Hz. The response time to CO/SF 6 gas is 93 s with a flow rate of 500 sccm. The detection limit of the CO sensor is 53 ppb, which realizes the accurate and timely perception of the SF 6 decomposition derivative CO and provides technical support for trouble-free operation of gas insulation equipment.

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Section: Differential Lock-in Amplification Technology Ofmentioning

confidence: 99%

Fiber-Optic Photoacoustic CO Sensor for Gas Insulation Equipment Monitoring Based on Cantilever Differential Lock-In Amplification and Optical Excitation Enhancement

Zhao,

Ma,

Wang

et al. 2024

Anal. Chem.

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“…Gas-insulated switchgear (GIS) mainly utilizes SF 6 gas as its insulating medium. Partial discharge faults inevitably occur in long-term operation, causing the breakdown of SF 6 into various low-fluorine sulfides. , Under microwater and microoxygen conditions, the low-fluorine sulfides produce various corrosive decomposition products which corrode insulating components and cause the electrical or thermal breakdown of the insulating medium. , Partial discharge is difficult to detect in the operations, preventative high-voltage tests, and maintenance due to its strong concealment . Using a gas sensor to detect the decomposition components of SF 6 is a common method for realizing online monitoring of the partial discharge in GIS. , …”

Section: Introductionmentioning

confidence: 99%

“…This article studied the adsorption and sensing performances of different amounts of the TiO 2 cluster doped into a graphene monolayer ( n TiO 2 -graphene, n = 1, 2, 3) toward SOF 2 and SO 2 F 2 based on density of states (DFT) calculations. The adsorption properties were analyzed by studying the adsorption energy, charge transfer, density of states (DOS), and partial density of states (PDOS). − This study enriches and develops the online monitoring methods of GIS and enhances the engineering application value of gas sensor detection technology for the online monitoring of electrical equipment …”

Section: Introductionmentioning

confidence: 99%

Adsorption and Sensing Performances of a TiO₂ Cluster-Doped Graphene Monolayer toward SOF₂ and SO₂F₂

Hao,

Gui,

Liu

2023

Langmuir

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Due to the high surface activity of metal atoms, it is difficult for doped metals to maintain long-term stability. Compared with other metal oxides, TiO2 graphene sensors have a higher sensing response and a larger specific surface area. However, there is currently no literature comparing and analyzing the effect of graphene-doped TiO2 on the adsorption performance of SF6 decomposition components. Therefore, this article investigated the adsorption performance of SF6 decomposition products: the distribution of SOF2 and SO2F2 on nTiO2 (n = 1,2,3)-doped graphene. In order to explore the interaction mechanism between gas molecules and these modified systems, their E ads, charge transfer, DOS, and PDOS were systematically studied. The doping of nTiO2 significantly improves the adsorption ability of graphene to gas molecules, discovers and enriches the online monitoring methods of GIS, and improves the engineering application value of GIS.

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“…Real-time monitoring of trace H 2 S concentrations is an urgent need for the safe and stable operation of the power system . The optical method , has certain advantages in H 2 S measurement. Utilizing tunable diode laser absorption spectroscopy (TDLAS) technology with an effective absorption path of 56.7 m, an H 2 S sensor with a detection limit of 224 ppb was designed .…”

mentioning

confidence: 99%

Ultrahigh Sensitive Trace Gas Sensing System with Dual Fiber-Optic Cantilever Multiplexing-Based Differential Photoacoustic Detection

Zhao,

Wang,

et al. 2024

Anal. Chem.

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An ultrahigh sensitive trace gas sensing system was presented with dual cantilever-based differential photoacoustic detection. By combining the double enhancement of multipass absorption and optical differential detection, the gas detection sensitivity was significantly improved. The dualchannel synchronous photoacoustic detection was realized by fiber-optic Fabry−Perot interference spectrum multiplexing. The photoacoustic signals detected by two fiber-optic cantilever microphones installed in a differential photoacoustic cell (DPAC) were out of phase, while the detected gas flow noises were in phase. The optical differential detection method achieved both highly sensitive optical interference measurement and differential noise suppression. In the multipass configuration, the interaction path between excitation light and target gas achieved 4.1 m, which improved the photoacoustic signal by an order of magnitude compared with a single reflection. The maximum gas flow allowed by the system based on the DPAC was 250 sccm, which realized the dynamic monitoring of H 2 S in the SF 6 background. The detection limit for H 2 S in SF 6 background was 5.1 ppb, which corresponds to the normalized noise equivalent absorption coefficient of 9 × 10 −10 cm −1 W Hz −1/2 .

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Simple technique of coupling a diode laser into a linear power buildup cavity for Raman gas sensing

Cited by 64 publications

References 23 publications

Fiber-Optic Photoacoustic CO Sensor for Gas Insulation Equipment Monitoring Based on Cantilever Differential Lock-In Amplification and Optical Excitation Enhancement

Fiber-Optic Photoacoustic CO Sensor for Gas Insulation Equipment Monitoring Based on Cantilever Differential Lock-In Amplification and Optical Excitation Enhancement

Adsorption and Sensing Performances of a TiO₂ Cluster-Doped Graphene Monolayer toward SOF₂ and SO₂F₂

Ultrahigh Sensitive Trace Gas Sensing System with Dual Fiber-Optic Cantilever Multiplexing-Based Differential Photoacoustic Detection

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Simple technique of coupling a diode laser into a linear power buildup cavity for Raman gas sensing

Cited by 64 publications

References 23 publications

Fiber-Optic Photoacoustic CO Sensor for Gas Insulation Equipment Monitoring Based on Cantilever Differential Lock-In Amplification and Optical Excitation Enhancement

Fiber-Optic Photoacoustic CO Sensor for Gas Insulation Equipment Monitoring Based on Cantilever Differential Lock-In Amplification and Optical Excitation Enhancement

Adsorption and Sensing Performances of a TiO2 Cluster-Doped Graphene Monolayer toward SOF2 and SO2F2

Ultrahigh Sensitive Trace Gas Sensing System with Dual Fiber-Optic Cantilever Multiplexing-Based Differential Photoacoustic Detection

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Adsorption and Sensing Performances of a TiO₂ Cluster-Doped Graphene Monolayer toward SOF₂ and SO₂F₂