What question did this study set out to answer?

The aim is to enhance the measurement of CO2 and other atmospheric parameters using an automated lidar system.

April 16, 2026Open Access

Automated CO

Key Points

The aim is to enhance the measurement of CO2 and other atmospheric parameters using an automated lidar system.
Extended the ARTHUS lidar system to include a CO2 measuring channel.
Utilized a narrow-band interference filter to target the CO2 Raman line.
Employed a frequency-tripled Nd:YAG laser for measurements.
Operated the system over several weeks to gather continuous data.
Achieved measurement uncertainties of less than 1.3 ppm at 1 km altitude.
Maintained system operations successfully for several weeks in 2023.
Demonstrated capabilities of profiling CO2, H2O, temperature, and particle characteristics.

Abstract

We have extended our automatic and continuously measuring ground-based Raman lidar ARTHUS (Atmospheric Raman Temperature and Humidity Sounder) with a CO2 channel. A narrow-band interference filter extracts the 2ν2 CO2 Raman line with 68 % peak transmission and 0.15 nm FWHM. We use a frequency-tripled Nd:YAG laser (200 Hz, 40 mJ in 2023, 100 mJ in 2024) and a 40-cm receiving telescope. With the current setup, we profile CO2, H2O and temperature as well as particle extinction coefficient and particle backscatter coefficient. We have operated this eye-safe system successfully in 2023 for several weeks at our university and continue to do so with a further improved system performance this spring. The first test measurements in 2023 achieved already uncertainties of <1.3 ppm at 1 km altitude with averaging of 4.4 h and 500 m at night.

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Automated CO

Key Points

Abstract

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