A near-infrared methane detection system using a 1.654 μm wavelength-modulated diode laser

By adopting a distributed feedback laser(DFBL) centered at 1.654 μm, a near-infrared(NIR) methane(CH4) detection system based on tunable diode laser absorption spectroscopy(TDLAS) is experimentally demonstrated. A laser temperature control as well as wavelength modulation module is developed to cont...

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Published inOptoelectronics letters Vol. 12; no. 2; pp. 140 - 143
Main Author 付洋 刘慧芳 隋越 李彬 叶玮琳 郑传涛 王一丁
Format Journal Article
LanguageEnglish
Published Tianjin Tianjin University of Technology 01.03.2016
Subjects
Lasers
Optical Devices
Optics
Photonics
Physics
Physics and Astronomy
分布反馈激光器
半导体激光器
可调谐二极管激光吸收光谱
检测系统
模拟温度控制器
波长调制
甲烷
近红外
A
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ISSN1673-1905
1993-5013
DOI10.1007/s11801-016-5243-y

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Summary:By adopting a distributed feedback laser(DFBL) centered at 1.654 μm, a near-infrared(NIR) methane(CH4) detection system based on tunable diode laser absorption spectroscopy(TDLAS) is experimentally demonstrated. A laser temperature control as well as wavelength modulation module is developed to control the laser's operation temperature. The laser's temperature fluctuation can be limited within the range of-0.02-0.02 °C, and the laser's emitting wavelength varies linearly with the temperature and injection current. An open reflective gas sensing probe is realized to double the absorption optical path length from 0.2 m to 0.4 m. Within the detection range of 0-0.01, gas detection experiments were conducted to derive the relation between harmonic amplitude and gas concentration. Based on the Allan deviation at an integral time of 1 s, the limit of detection(Lo D) is decided to be 2.952×10-(-5) with a path length of 0.4 m, indicating a minimum detectable column density of -1.2×10-(-5) m. Compared with our previously reported NIR CH_4 detection system, this system exhibits some improvement in both optical and electrical structures, including the analogue temperature controller with less software consumption, simple and reliable open reflective sensing probe.
Bibliography:reflective deviation methane modulated Allan tunable analogue fluctuation decided length
By adopting a distributed feedback laser(DFBL) centered at 1.654 μm, a near-infrared(NIR) methane(CH4) detection system based on tunable diode laser absorption spectroscopy(TDLAS) is experimentally demonstrated. A laser temperature control as well as wavelength modulation module is developed to control the laser's operation temperature. The laser's temperature fluctuation can be limited within the range of-0.02-0.02 °C, and the laser's emitting wavelength varies linearly with the temperature and injection current. An open reflective gas sensing probe is realized to double the absorption optical path length from 0.2 m to 0.4 m. Within the detection range of 0-0.01, gas detection experiments were conducted to derive the relation between harmonic amplitude and gas concentration. Based on the Allan deviation at an integral time of 1 s, the limit of detection(Lo D) is decided to be 2.952×10-(-5) with a path length of 0.4 m, indicating a minimum detectable column density of -1.2×10-(-5) m. Compared with our previously reported NIR CH_4 detection system, this system exhibits some improvement in both optical and electrical structures, including the analogue temperature controller with less software consumption, simple and reliable open reflective sensing probe.
12-1370/TN
ISSN:1673-1905
1993-5013
DOI:10.1007/s11801-016-5243-y