Abstract
Abstract. Airborne imaging remote sensing is increasingly used to map the spatial distribution of nitrogen dioxide (NO2) in cities. Despite the small ground-pixel size of the sensors, the measured NO2 distributions are much smoother than one would expect from high-resolution model simulations of NO2 over cities. This could partly be caused by 3D radiative transfer effects due to observation geometry, adjacency effects and effects of buildings. Here, we present a case study of imaging a synthetic NO2 distribution for a district of Zurich using the 3D MYSTIC (Monte carlo code for the phYSically correct Tracing of photons In Cloudy atmospheres) solver of the libRadtran radiative transfer library. We computed NO2 slant column densities (SCDs) using the recently implemented 3D-box air mass factors (3D-box AMFs) and a new urban canopy module to account for the effects of buildings. We found that for a single ground pixel (50 m × 50 m) more than 50 % of the sensitivity is located outside of the pixel, primarily in the direction of the main optical path between sun, ground pixel, and instrument. Consequently, NO2 SCDs are spatially smoothed, which results in an increase over roads when they are parallel to the optical path and a decrease otherwise. When buildings are included, NO2 SCDs are reduced on average by 5 % due to the reduced sensitivity to NO2 in the shadows of the buildings. The effects of buildings also introduce a complex pattern of variability in SCDs that would show up in airborne observations as an additional noise component (about 12 µmol m−2) similar to the magnitude of typical measurement uncertainties. The smearing of the SCDs cannot be corrected using 1D-layer AMFs that assume horizontal homogeneity and thus remains in the final NO2 map. The 3D radiative transfer effects by including buildings need to be considered to compute more accurate AMFs and to reduce biases in NO2 vertical columns obtained from high-resolution city-scale NO2 remote sensing.
Highlights
Nitrogen oxides (NOx = NO + NO2) are key air pollutants mainly emitted by fuel combustion, traffic, heating systems, industrial facilities and power plants
We compare total air mass factors (AMFs) for the complete image obtained from an airborne instrument flying over the study domain as illustrated in Fig. 2c between the solution obtained with the 3D and the 1D radiative transfer model (RTM) to illustrate the importance of 3D radiative transfer effects on the slant column densities (SCDs) measurements
The observed difference may partly be explained by atmospheric mixing more strongly affecting total columns than near-surface concentrations, but could be caused by complex 3D radiative transfer effects in cities
Summary
Nitrogen oxides (NOx = NO + NO2) are key air pollutants mainly emitted by fuel combustion, traffic, heating systems, industrial facilities and power plants. An attractive possibility to create high-resolution maps (< 100 m) of the NO2 distribution in cities is to use an airborne imaging spectrometer. This was first demonstrated for measurements from the Airborne Prism Experiment (APEX) of a Swiss–Belgium consortium (Popp et al, 2012; Tack et al, 2017) and the Geostationary Trace gas and Aerosol Sensor Optimization (GeoTASO) spectrometer (Nowlan et al, 2016) developed in the United States. Schwaerzel et al.: 3D radiative transfer over cities with buildings
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