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<p>The Tropospheric Monitoring Instrument (TROPOMI), aboard the Sentinel-5 Precursor (S5P) satellite, launched on 13 October 2017, provides measurements of atmospheric trace gases and of cloud and aerosol properties at an unprecedented spatial resolution of approximately <span class="inline-formula">7×3.5</span>&thinsp;km<span class="inline-formula">²</span> (approx. <span class="inline-formula">5.5×3.5</span>&thinsp;km<span class="inline-formula">²</span> as of 6 August 2019), achieving near-global coverage in 1&thinsp;d. The retrieval of nitrogen dioxide (<span class="inline-formula">NO₂</span>) concentrations is a three-step procedure: slant column density (SCD) retrieval, separation of the SCD in its stratospheric and tropospheric components, and conversion of these into vertical column densities. This study focusses on the TROPOMI <span class="inline-formula">NO₂</span> SCD retrieval: the retrieval method used, the stability of the SCDs and the SCD uncertainties, and a comparison with the Ozone Monitoring Instrument (OMI) <span class="inline-formula">NO₂</span> SCDs.</p> <p>The statistical uncertainty, based on the spatial variability of the SCDs over a remote Pacific Ocean sector, is 8.63&thinsp;<span class="inline-formula">µ</span>mol&thinsp;m<span class="inline-formula">⁻²</span> for all pixels (9.45&thinsp;<span class="inline-formula">µ</span>mol&thinsp;m<span class="inline-formula">⁻²</span> for clear-sky pixels), which is very stable over time and some 30&thinsp;% less than the long-term average over OMI–QA4ECV data (since the pixel size reduction TROPOMI uncertainties are <span class="inline-formula">∼8</span>&thinsp;% larger). The SCD uncertainty reported by the differential optical absorption spectroscopy (DOAS) fit is about 10&thinsp;% larger than the statistical uncertainty, while for OMI–QA4ECV the DOAS uncertainty is some 20&thinsp;% larger than its statistical uncertainty. Comparison of the SCDs themselves over the Pacific Ocean, averaged over 1 month, shows that TROPOMI is about 5&thinsp;% higher than OMI–QA4ECV, which seems to be due mainly to the use of the so-called intensity offset correction in OMI–QA4ECV but not in TROPOMI: turning that correction off means about 5&thinsp;% higher SCDs. The row-to-row variation in the SCDs of TROPOMI, the “stripe amplitude”, is 2.15&thinsp;<span class="inline-formula">µ</span>mol&thinsp;m<span class="inline-formula">⁻²</span>, while for OMI–QA4ECV it is a factor of <span class="inline-formula">∼2</span> (<span class="inline-formula">∼5</span>) larger in 2005 (2018); still, a so-called stripe correction of this non-physical across-track variation is useful for TROPOMI data. In short, TROPOMI shows a superior performance compared with OMI–QA4ECV and operates as anticipated from instrument specifications.</p> <p>The TROPOMI data used in this study cover 30 April 2018 up to 31 January 2020.</p>