Title :
Chemical sensors based on quantum cascade lasers
Author :
Kosterev, Anatoliy A. ; Tittel, Frank K.
Author_Institution :
Rice Quantum Inst., Rice Univ., Houston, TX, USA
fDate :
6/1/2002 12:00:00 AM
Abstract :
There is an increasing need in many chemical sensing applications ranging from industrial process control to environmental science and medical diagnostics for fast, sensitive, and selective gas detection based on laser spectroscopy. The recent availability of novel pulsed and CW quantum cascade distributed feedback (QC-DFB) lasers as mid-infrared spectroscopic sources address this need. A number of spectroscopic techniques have been demonstrated worldwide by several groups. For example, the authors have employed QC-DFB lasers for the monitoring and quantification of several trace gases and isotopic species in ambient air at ppmv and ppbv levels by means of direct absorption, wavelength modulation, and cavity enhanced and cavity ringdown spectroscopy
Keywords :
distributed feedback lasers; gas sensors; infrared sources; infrared spectroscopy; laser cavity resonators; measurement by laser beam; modulation spectroscopy; quantum well lasers; spectrochemical analysis; spectroscopic light sources; CW quantum cascade distributed feedback lasers; QC-DFB lasers; cavity enhanced spectroscopy; cavity ringdown spectroscopy; chemical sensors; direct absorption; fast sensitive selective gas detection; infrared laser absorption spectroscopy; isotopic species; laser spectroscopy; mid-infrared spectroscopic sources; molecular trace gases; pulsed quantum cascade distributed feedback lasers; quantum cascade lasers; trace gas detection; wavelength modulation spectroscopy; Chemical industry; Chemical lasers; Chemical processes; Chemical sensors; Distributed feedback devices; Gas lasers; Laser feedback; Laser theory; Quantum cascade lasers; Spectroscopy;
Journal_Title :
Quantum Electronics, IEEE Journal of
DOI :
10.1109/JQE.2002.1005408
