Abstract
Abstract. A reduction of the anthropogenic emissions of CO2 (carbon dioxide) is necessary to stop or slow down man-made climate change. To verify mitigation strategies, a global monitoring system such as the envisaged European Copernicus anthropogenic CO2 monitoring mission (CO2M) is required. Those satellite data are going to be complemented and validated with airborne measurements. Unmanned aerial vehicle (UAV)-based measurements can provide a cost-effective way to contribute to these activities. Here, we present the development of an sUAS (small unmanned aircraft system) to quantify the CO2 emissions of a nearby point source from its downwind mass flux without the need for any ancillary data. Specifically, CO2 is measured by an NDIR (non-dispersive infrared) detector, and the wind speed and direction are measured with a 2-D ultrasonic acoustic resonance anemometer. By means of laboratory measurements and an in-flight validation at the ICOS (Integrated Carbon Observation System) atmospheric station Steinkimmen (STE) near Bremen, Germany, we estimate that the individual CO2 measurements have a precision of 3 ppm and that CO2 enhancements can be determined with an accuracy of 1.3 % or 0.9 ppm, whichever is larger. We introduce an anemometer calibration method to minimize the effect of rotor downwash on the wind measurements. This method derives the fit parameters of a linear calibration model accounting for scaling, rotation, and a potential constant bias. For this purpose, it analyzes wind measurements taken while following a suitable flight pattern and assuming stationary wind conditions. From the calibration and validation experiments, we estimate the single measurement precision of the horizontal wind speed to be 0.40 m s−1 and the accuracy to be 0.33 m s−1. By means of two flights downwind of the ExxonMobil natural gas processing facility in Großenkneten about 40 km west of Bremen, Germany, we demonstrate how the measurements of elevated CO2 concentrations can be used to infer mass fluxes of atmospheric CO2 related to the emissions of the facility.
Highlights
CO2 emissions are the primary cause of man-made climate change, and in order to limit this, a reduction of emissions is necessary (IPCC, 2013)
By means of two flights downwind of the ExxonMobil natural gas processing facility in Großenkneten about 40 km west of Bremen, Germany, we demonstrate how the measurements of elevated CO2 concentrations can be used to infer mass fluxes of atmospheric CO2 related to the emissions of the facility
Large parts of the anthropogenic CO2 emissions originate from point sources such as coal- or gas-fired power plants and observing systems are needed to verify mitigation strategies through independent measurements (Pinty et al, 2017)
Summary
CO2 (carbon dioxide) emissions are the primary cause of man-made climate change, and in order to limit this, a reduction of emissions is necessary (IPCC, 2013). M. Reuter et al.: Development of an sUAS to derive CO2 emissions able measurements under conditions not suitable for satellite measurements, e.g., in cloud-contaminated scenes, during nighttime, or at facilities with emissions below the satellite’s detection limit. The quantification of emissions with the mass balance approach using atmospheric measurements downwind of the source requires knowledge of the atmospheric concentration of CO2, the wind speed, and the density of air. The system was required to be reliable and affordable, and to be realized within a relatively short development phase For this reason, we decided to use only commercially available and mature components for the UAV as well as the sensor equipment. 5, we quantify the performance of our atmospheric measurements with a focus on CO2 and wind by analyzing two validation flights at the ICOS (Integrated Carbon Observation System) atmospheric station Steinkimmen (STE) near Bremen, Germany.
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