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Abstract

Based on our experimental study of spectral characteristics of an improved compact CO laser system, the prospects of using such a laser system for solving urgent problems of atmospheric sounding were demonstrated. An increase in the number of laser lines due to intracavity generation of the second harmonic and sum-frequencies in a nonlinear zinc germanium phosphide (ZnGeP₂) crystal enriches capabilities of the laser. It was shown that such a CO laser system with frequency conversion in ZnGeP₂ crystal can be used for detection and measuring concentration of at least 14 minor natural and pollution gases components of the atmosphere. The advantages and disadvantages of various laser operation modes, and the prospects for using its radiation for atmospheric remote sensing in various spectral ranges are discussed.

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Keywords

Carbon monoxide laser CO laser mid-infrared spectroscopy MIR gas analysis multicomponent gas analysis atmosphere sensing zinc germanium phosphide ZnGeP2 crystal second harmonic generation sum frequency generation

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Compact Radio Frequency Discharge-Pumped Slab CO Laser System with a Zinc Germanium Phosphide (ZnGeP 2 ) Sum-Frequency Generator for Remote Sensing of the Atmosphere

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