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Literature DB >> 31939293

ppb-Level SO₂ Photoacoustic Sensors with a Suppressed Absorption-Desorption Effect by Using a 7.41 μm External-Cavity Quantum Cascade Laser.

Xukun Yin^1,2,3, Hongpeng Wu^1,2, Lei Dong^1,2, Biao Li^1,2, Weiguang Ma^1,2, Lei Zhang^1,2, Wangbao Yin^1,2, Liantuan Xiao^1,2, Suotang Jia^1,2, Frank K Tittel³.

Abstract

A sensitive photoacoustic sensor system for the detection of ppb-level sulfur dioxide (SO2) was developed by the use of a continuous-wave room-temperature, high-power quantum cascade laser (QCL) with an external diffraction grating cavity geometry. The excitation wavelength of the QCL was set to 7.41 μm for the strongest SO2 absorption line strength. A custom-made differential photoacoustic cell (PAC) with two identical resonators was designed to allow a gas flow rate up to 1200 sccm. A qualitative theoretical model was employed in order to understand the dynamic adsorption and desorption processes of SO2 in the PAC walls. A 1σ detection limit of 2.45 ppb, corresponding to a normalized noise equivalent absorption value of 3.32 × 10-9 cm-1 W/Hz1/2, was achieved after measures for suppressing the absorption-desorption effect were taken.

Entities: Chemical Species

Keywords: adsorption−desorption effects; differential photoacoustic cell; photoacoustic spectroscopy; quantum cascade lasers; sulfur dioxide detection; trace gas sensor

Mesh：

Year: 2020 PMID： 31939293 DOI： 10.1021/acssensors.9b02448

Source DB: PubMed Journal: ACS Sens ISSN： 2379-3694 Impact factor: 7.711

Keyword Cloud
Cited

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