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1. 5 years of Sentinel-5P TROPOMI operational ozone profiling and geophysical validation using ozonesonde and lidar ground-based networks.

Author

Keppens, Arno, Di Pede, Serena, Hubert, Daan, Lambert, Jean-Christopher, Veefkind, Pepijn, Sneep, Maarten, De Haan, Johan, ter Linden, Mark, Leblanc, Thierry, Compernolle, Steven, Verhoelst, Tijl, Granville, José, Nath, Oindrila, Fjæraa, Ann Mari, Boyd, Ian, Niemeijer, Sander, Van Malderen, Roeland, Smit, Herman G. J., Duflot, Valentin, and Godin-Beekmann, Sophie

Subjects
TROPOSPHERIC ozone, OZONE, LIDAR, OZONE layer, ZENITH distance, DEGREES of freedom, STRATOSPHERE
Abstract

The Sentinel-5 Precursor (S5P) satellite operated by the European Space Agency has carried the TROPOspheric Monitoring Instrument (TROPOMI) on a Sun-synchronous low-Earth orbit since 13 October 2017. The S5P mission has acquired more than 5 years of TROPOMI nadir ozone profile data retrieved from the level 0 to 1B processor version 2.0 and the level 1B to 2 optimal-estimation-based processor version 2.4.0. The latter is described in detail in this work, followed by the geophysical validation of the resulting ozone profiles for the period May 2018 to April 2023. Comparison of TROPOMI ozone profile data to co-located ozonesonde and lidar measurements used as references concludes to a median agreement better than 5 % to 10 % in the troposphere. The bias goes up to - 15 % in the upper stratosphere (35–45 km) where it can exhibit vertical oscillations. The comparisons show a dispersion of about 30 % in the troposphere and 10 % to 20 % in the upper troposphere to lower stratosphere and in the middle stratosphere, which is close to mission requirements. Chi-square tests of the observed differences confirm on average the validity of the ex ante (prognostic) satellite and ground-based data uncertainty estimates in the middle stratosphere above about 20 km. Around the tropopause and below, the mean chi-square value increases up to about four, meaning that the ex ante TROPOMI uncertainty is underestimated. The information content of the ozone profile retrieval is characterised by about five to six vertical subcolumns of independent information and a vertical sensitivity (i.e. the fraction of the information that originates from the measurement) nearly equal to unity at altitudes from about 20 to 50 km, decreasing rapidly at altitudes above and below. The barycentre of the retrieved information is usually close to the nominal retrieval altitude in the 20–50 km altitude range, with positive and negative offsets of up to 10 km below and above this range, respectively. The effective vertical resolution of the profile retrieval usually ranges within 10–15 km, with a minimum close to 7 km in the middle stratosphere. Increased sensitivities and higher effective vertical resolutions are observed at higher solar zenith angles (above about 60°), as can be expected, and correlate with higher retrieved ozone concentrations. The vertical sensitivity of the TROPOMI tropospheric ozone retrieval is found to depend on the solar zenith angle, which translates into a seasonal and meridian dependence of the bias with respect to reference measurements. A similar although smaller effect can be seen for the viewing zenith angle. Additionally, the bias is negatively correlated with the surface albedo for the lowest three ozone subcolumns (0–18 km), despite the albedo's apparently slightly positive correlation with the retrieval degrees of freedom in the signal. For the 5 years of TROPOMI ozone profile data that are available now, an overall positive drift is detected for the same three subcolumns, while a negative drift is observed above (24–32 km), resulting in a negligible vertically integrated drift. [ABSTRACT FROM AUTHOR]

Published
2024
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3. Five years of Sentinel-5p TROPOMI operational ozone profiling and geophysical validation using ozonesonde and lidar ground-based networks

Author

Keppens, Arno, primary, Di Pede, Serena, additional, Hubert, Daan, additional, Lambert, Jean-Christopher, additional, Veefkind, Pepijn, additional, Sneep, Maarten, additional, De Haan, Johan, additional, ter Linden, Mark, additional, Leblanc, Thierry, additional, Compernolle, Steven, additional, Verhoelst, Tijl, additional, Granville, José, additional, Nath, Oindrila, additional, Fjaeraa, Ann Mari, additional, Boyd, Ian, additional, Niemeijer, Sander, additional, Van Malderen, Roeland, additional, Smit, Herman G. J., additional, Duflot, Valentin, additional, Godin-Beekmann, Sophie, additional, Johnson, Bryan J., additional, Steinbrecht, Wolfgang, additional, Tarasick, David W., additional, Kollonige, Debra E., additional, Stauffer, Ryan M., additional, Thompson, Anne M., additional, Dehn, Angelika, additional, and Zehner, Claus, additional

Published
2024
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4. Random Forest Classifier for Cloud Clearing of the Operational TROPOMI XCH 4 Product.

Author

Borsdorff, Tobias, Martinez-Velarte, Mari C., Sneep, Maarten, ter Linden, Mark, and Landgraf, Jochen

Subjects
RANDOM forest algorithms, CLOUD forests, PEARSON correlation (Statistics), CLOUD storage, ELECTRONIC data processing
Abstract

The TROPOMI XCH4 data product requires rigorous cloud filtering to achieve a product accuracy of <1%. To this end, operational XCH4 data processing has been based on SUOMI-NPP VIIRS cloud observations. However, SUOMI-NPP is nearing the end of its operational life and has encountered malfunctions in 2022 and 2023. In this study, we introduce a novel machine learning cloud-clearing approach based on a random forest classifier (RFC). The RFC is trained on collocated TROPOMI and SUOMI-NPP VIIRS data to emulate VIIRS-like cloud clearing. After training, cloud masking requires only TROPOMI data, and so becomes operationally independent of SUOMI-NPP. We demonstrate the RFC approach by applying cloud clearing to operational TROPOMI XCH4 data for August 2022, a period in which VIIRS was not operational. For validation, we analyze the TROPOMI XCH4 data at 12 TCCON stations. Comparison of cloud clearing using the RFC and the original VIIRS method reveals excellent agreement with a similar station-to-station bias (−7.4 ppb versus −5.6 ppb), a similar standard deviation of the station-to-station bias (11.6 ppb versus 12 ppb), and the same Pearson correlation coefficient of 0.9. Remarkably, the RFC cloud clearing provides a slightly higher volume of data (2182 versus 2035 daily means) and appears to have fewer outliers. Since 21 November 2023, the RFC approach is part of the operational processing chain of the European Space Agency (ESA). For now, the default practice is to utilize SNPP-VIIRS when accessible. Only in cases where VIIRS data are unavailable do we resort to the RFC cloud mask. [ABSTRACT FROM AUTHOR]

Published
2024
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5. Five years of Sentinel-5p TROPOMI operational ozone profiling and geophysical validation using ozonesonde and lidar ground-based networks.

Author

Keppens, Arno, Di Pede, Serena, Hubert, Daan, Lambert, Jean-Christopher, Veefkind, Pepijn, Sneep, Maarten, De Haan, Johan, ter Linden, Mark, Leblanc, Thierry, Compernolle, Steven, Verhoelst, Tijl, Granville, José, Nath, Oindrila, Fjæraa, Ann Mari, Boyd, Ian, Niemeijer, Sander, Van Malderen, Roeland, Smit, Herman G. J., Duflot, Valentin, and Godin-Beekmann, Sophie

Subjects
TROPOSPHERIC ozone, OZONE, LIDAR, ZENITH distance, DEGREES of freedom, STRATOSPHERE
Abstract

The Sentinel-5 Precursor (S5P) satellite operated by the European Space Agency (ESA) carries the TROPOspheric Monitoring Instrument (TROPOMI) on a Sun-synchronous low-Earth orbit since October 13, 2017. The S5P mission has acquired more than five years of TROPOMI nadir ozone profile data retrieved from the Level-0-to-1B processor version 2.0 and the Level-1B-to-2 Optimal Estimation based processor version 2.4.0. The latter is described in detail in this work, followed by the geophysical validation of the resulting ozone profiles for the period May 2018 to April 2023. Comparison of TROPOMI ozone profile data to co-located ozonesonde and lidar measurements used as references, concludes to a median agreement better than 5 to 10 % in the troposphere. The bias goes up to -15 % in the upper stratosphere (35-45 km) where it can exhibit vertical oscillations. The comparisons show a dispersion of about 30 % in the troposphere and 10 to 20 % in the upper troposphere to lower stratosphere (UTLS) and in the middle stratosphere, which is close to mission requirements. Chi-square tests of the observed differences confirm on average the validity of the ex-ante (prognostic) satellite and ground-based data uncertainty estimates in the middle stratosphere, above about 20 km. Around the tropopause and below, the mean chi-square value increases up to about four, meaning that the ex-ante TROPOMI uncertainty is underestimated. The information content of the ozone profile retrieval is characterised by about five to six vertical sub-columns of independent information and a vertical sensitivity nearly equal to unity at altitudes from about 20 to 50 km, decreasing rapidly at altitudes above and below. The barycentre of the retrieved information is usually close to the nominal retrieval altitude in the 20-50 km altitude range, with positive and negative offsets of up to 10 km below and above this range, respectively. The effective vertical resolution of the profile retrieval usually ranges within 10-15 km, with a minimum close to 7 km in the middle stratosphere. Increased sensitivity and higher effective vertical resolution are observed at higher solar zenith angle (SZA, above about 60°C), as can be expected, and correlate with higher retrieved ozone concentrations. The vertical sensitivity of the TROPOMI tropospheric ozone amount is found to depend on solar zenith angle, which translates into a seasonal and meridian dependence of its bias with respect to reference measurements. A similar although smaller effect can be seen for the viewing zenith angle (VZA). Additionally, the bias is negatively correlated with the surface albedo for the 6-12 km ozone subcolumn, despite the latter's apparently slightly positive correlation with the retrieval degrees of freedom in the signal. For the five years of TROPOMI ozone profile data that are available now, an overall positive drift is detected for the lowest three subcolumns (0-18 km), while a negative drift is observed for the two subcolumns above (18-32 km), resulting in a negligible vertically integrated drift. [ABSTRACT FROM AUTHOR]

Published
2024
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8. Assessing the quality of the Sentinel-5p TROPOMI cloud products and their reprocessing using ground-based Cloudnet data

Author

Compernolle, Steven, primary, Argyrouli, Athina, additional, Lutz, Ronny, additional, Sneep, Maarten, additional, Lambert, Jean-Christopher, additional, Fjaeraa, Ann Mari, additional, Granville, José, additional, Hubert, Daan, additional, Keppens, Arno, additional, Loyola, Diego, additional, O'Connor, Ewan, additional, Pinardi, Gaia, additional, Rasson, Olivier, additional, Romahn, Fabian, additional, Stammes, Piet, additional, Verhoelst, Tijl, additional, and Wang, Ping, additional

Published
2023
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9. Intercomparison of Sentinel-5P TROPOMI cloud products for tropospheric trace gas retrievals

Author

Latsch, Miriam, primary, Richter, Andreas, additional, Eskes, Henk, additional, Sneep, Maarten, additional, Wang, Ping, additional, Veefkind, Pepijn, additional, Lutz, Ronny, additional, Loyola, Diego, additional, Argyrouli, Athina, additional, Valks, Pieter, additional, Wagner, Thomas, additional, Sihler, Holger, additional, van Roozendael, Michel, additional, Theys, Nicolas, additional, Yu, Huan, additional, Siddans, Richard, additional, and Burrows, John P., additional

Published
2022
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11. Supplementary material to &quot;Intercomparison of Sentinel-5P TROPOMI cloud products for tropospheric trace gas retrievals&quot;

Author

Latsch, Miriam, primary, Richter, Andreas, additional, Eskes, Henk, additional, Sneep, Maarten, additional, Wang, Ping, additional, Veefkind, Pepijn, additional, Lutz, Ronny, additional, Loyola, Diego, additional, Argyrouli, Athina, additional, Valks, Pieter, additional, Wagner, Thomas, additional, Sihler, Holger, additional, van Roozendael, Michel, additional, Theys, Nicolas, additional, Yu, Huan, additional, Siddans, Richard, additional, and Burrows, John P., additional

Published
2022
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12. Sentinel-5P TROPOMI NO2retrieval: impact of version v2.2 improvements and comparisons with OMI and ground-based data

Author

Van Geffen, Jos (author), Eskes, Henk (author), Compernolle, Steven (author), Pinardi, Gaia (author), Verhoelst, Tijl (author), Lambert, Jean Christopher (author), Sneep, Maarten (author), Linden, Mark Ter (author), Veefkind, j. Pepijn (author), Van Geffen, Jos (author), Eskes, Henk (author), Compernolle, Steven (author), Pinardi, Gaia (author), Verhoelst, Tijl (author), Lambert, Jean Christopher (author), Sneep, Maarten (author), Linden, Mark Ter (author), and Veefkind, j. Pepijn (author)

Abstract

Nitrogen dioxide (NO2) is one of the main data products measured by the Tropospheric Monitoring Instrument (TROPOMI) on the Sentinel-5 Precursor (S5P) satellite, which combines a high signal-to-noise ratio with daily global coverage and high spatial resolution. TROPOMI provides a valuable source of information to monitor emissions from local sources such as power plants, industry, cities, traffic and ships, and variability of these sources in time. Validation exercises of NO2 v1.2-v1.3 data, however, have revealed that TROPOMI's tropospheric vertical column densities (VCDs) are too low by up to 50ĝ€¯% over highly polluted areas. These findings are mainly attributed to biases in the cloud pressure retrieval, the surface albedo climatology and the low resolution of the a priori profiles derived from global simulations of the TM5-MP chemistry model. This study describes improvements in the TROPOMI NO2 retrieval leading to version v2.2, operational since 1 July 2021. Compared to v1.x, the main changes are the following. (1) The NO2-v2.2 data are based on version-2 level-1b (ir)radiance spectra with improved calibration, which results in a small and fairly homogeneous increase in the NO2 slant columns of 3% to 4%, most of which ends up as a small increase in the stratospheric columns. (2) The cloud pressures are derived with a new version of the FRESCO cloud retrieval already introduced in NO2-v1.4, which led to a lowering of the cloud pressure, resulting in larger tropospheric NO2 columns over polluted scenes with a small but non-zero cloud coverage. (3) For cloud-free scenes a surface albedo correction is introduced based on the observed reflectance, which also leads to a general increase in the tropospheric NO2 columns over polluted scenes of order 15%. (4) An outlier removal was implemented in the spectral fit, which increases the number of good-quality retrievals over the South Atlantic Anomaly region and over bright clouds where saturation may occur. (5) Snow/ic, Atmospheric Remote Sensing

Published
2022
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13. Improved monitoring of shipping NO2 with TROPOMI : Decreasing NOx emissions in European seas during the COVID-19 pandemic

Author

Riess, Tobias Christoph Valentin Werner, Boersma, Klaas Folkert, Van Vliet, Jasper, Peters, Wouter, Sneep, Maarten, Eskes, Henk, Van Geffen, Jos, Riess, Tobias Christoph Valentin Werner, Boersma, Klaas Folkert, Van Vliet, Jasper, Peters, Wouter, Sneep, Maarten, Eskes, Henk, and Van Geffen, Jos

Abstract

TROPOMI (TROPOspheric Monitoring Instrument) measurements of tropospheric NO2 columns provide powerful information on emissions of air pollution by ships on open sea. This information is potentially useful for authorities to help determine the (non-)compliance of ships with increasingly stringent NOx emission regulations. We find that the information quality is improved further by recent upgrades in the TROPOMI cloud retrieval and an optimal data selection. We show that the superior spatial resolution of TROPOMI allows for the detection of several lanes of NO2 pollution ranging from the Aegean Sea near Greece to the Skagerrak in Scandinavia, which have not been detected with other satellite instruments before. Additionally, we demonstrate that under conditions of sun glint TROPOMI's vertical sensitivity to NO2 in the marine boundary layer increases by up to 60g %. The benefits of sun glint are most prominent under clear-sky situations when sea surface winds are low but slightly above zero (±2g mg s-1). Beyond spatial resolution and sun glint, we examine for the first time the impact of the recently improved cloud algorithm on the TROPOMI NO2 retrieval quality, both over sea and over land. We find that the new FRESCO+ (Fast Retrieval Scheme for Clouds from the Oxygen A band) wide algorithm leads to 50g hPa lower cloud pressures, correcting a known high bias, and produces 1-4×1015g molec.g cm-2 higher retrieved NO2 columns, thereby at least partially correcting for the previously reported low bias in the TROPOMI NO2 product. By training an artificial neural network on the four available periods with standard and FRESCO+g wide test retrievals, we develop a historic, consistent TROPOMI NO2 data set spanning the years 2019 and 2020. This improved data set shows stronger (35g %-75g %) and sharper (10g %-35g %) shipping NO2 signals compared to co-sampled measurements from OMI. We apply our improved data set to investigate the impact of the COVID-19 pandemic on ship NO2 pol

Published
2022

14. Sentinel-5P TROPOMI NO2retrieval : impact of version v2.2 improvements and comparisons with OMI and ground-based data

Author

van Geffen, Jos, Eskes, Henk, Compernolle, Steven, Pinardi, Gaia, Verhoelst, Tijl, Lambert, Jean Christopher, Sneep, Maarten, Linden, Mark Ter, Ludewig, Antje, Folkert Boersma, K., Pepijn Veefkind, J., van Geffen, Jos, Eskes, Henk, Compernolle, Steven, Pinardi, Gaia, Verhoelst, Tijl, Lambert, Jean Christopher, Sneep, Maarten, Linden, Mark Ter, Ludewig, Antje, Folkert Boersma, K., and Pepijn Veefkind, J.

Abstract

Nitrogen dioxide (NO2) is one of the main data products measured by the Tropospheric Monitoring Instrument (TROPOMI) on the Sentinel-5 Precursor (S5P) satellite, which combines a high signal-to-noise ratio with daily global coverage and high spatial resolution. TROPOMI provides a valuable source of information to monitor emissions from local sources such as power plants, industry, cities, traffic and ships, and variability of these sources in time. Validation exercises of NO2 v1.2-v1.3 data, however, have revealed that TROPOMI's tropospheric vertical column densities (VCDs) are too low by up to 50ĝ€¯% over highly polluted areas. These findings are mainly attributed to biases in the cloud pressure retrieval, the surface albedo climatology and the low resolution of the a priori profiles derived from global simulations of the TM5-MP chemistry model. This study describes improvements in the TROPOMI NO2 retrieval leading to version v2.2, operational since 1 July 2021. Compared to v1.x, the main changes are the following. (1) The NO2-v2.2 data are based on version-2 level-1b (ir)radiance spectra with improved calibration, which results in a small and fairly homogeneous increase in the NO2 slant columns of 3% to 4%, most of which ends up as a small increase in the stratospheric columns. (2) The cloud pressures are derived with a new version of the FRESCO cloud retrieval already introduced in NO2-v1.4, which led to a lowering of the cloud pressure, resulting in larger tropospheric NO2 columns over polluted scenes with a small but non-zero cloud coverage. (3) For cloud-free scenes a surface albedo correction is introduced based on the observed reflectance, which also leads to a general increase in the tropospheric NO2 columns over polluted scenes of order 15%. (4) An outlier removal was implemented in the spectral fit, which increases the number of good-quality retrievals over the South Atlantic Anomaly region and over bright clouds where saturation may occur. (5) Snow/ice i

Published
2022

15. Sentinel-5P TROPOMI NO&lt;sub&gt;2&lt;/sub&gt; retrieval: impact of version v2.2 improvements and comparisons with OMI and ground-based data

Author

van Geffen, Jos, primary, Eskes, Henk, additional, Compernolle, Steven, additional, Pinardi, Gaia, additional, Verhoelst, Tijl, additional, Lambert, Jean-Christopher, additional, Sneep, Maarten, additional, ter Linden, Mark, additional, Ludewig, Antje, additional, Boersma, K. Folkert, additional, and Veefkind, J. Pepijn, additional

Published
2022
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17. Sentinel-5P TROPOMI NO2 retrieval: impact of version v2.2 improvements and comparisons with OMI and ground-based data

Author

van Geffen, Jos, primary, Eskes, Henk, additional, Compernolle, Steven, additional, Pinardi, Gaia, additional, Verhoelst, Tijl, additional, Lambert, Jean-Christopher, additional, Sneep, Maarten, additional, ter Linden, Mark, additional, Ludewig, Antje, additional, Boersma, K. Folkert, additional, and Veefkind, J. Pepijn, additional

Published
2021
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20. Validation of the Sentinel-5 Precursor TROPOMI cloud data with Cloudnet, Aura OMI O2-O2, MODIS, and Suomi-NPP VIIRS

Author

Compernolle, Steven, Argyrouli, Athina, Lutz, Ronny, Sneep, Maarten, Lambert, Jean-Christopher, Fjæraa, Ann Mari, Hubert, Daan, Keppens, Arno, Loyola, Diego, O'Connor, Ewan, Romahn, Fabian, Stammes, Piet, Verhoelst, Tijl, and Wang, Ping

Subjects
Remote Sensing, Clouds, Validation, TROPOMI, Atmosphärenprozessoren
Abstract

Accurate knowledge of cloud properties is essential to the measurement of atmospheric composition from space. In this work we assess the quality of the cloud data from three Copernicus Sentinel-5 Precursor (S5P) TROPOMI cloud products: (i) S5P OCRA/ROCINN_CAL (Optical Cloud Recognition Algorithm/Retrieval of Cloud Information using Neural Networks;Clouds-As-Layers), (ii) S5P OCRA/ROCINN_CRB (Clouds-as-Reflecting Boundaries), and (iii) S5P FRESCO-S (Fast Retrieval Scheme for Clouds from Oxygen absorption bands – Sentinel). Target properties of this work are cloud-top height and cloud optical thickness (OCRA/ROCINN_CAL), cloud height (OCRA/ROCINN_CRB and FRESCO-S), and radiometric cloud fraction (all three algorithms). The analysis combines (i) the examination of cloud maps for artificial geographical patterns, (ii) the comparison to other satellite cloud data (MODIS, NPP-VIIRS, and OMI O2–O2), and (iii) ground-based validation with respect to correlative observations (30 April 2018 to 27 February 2020) from the Cloudnet network of ceilometers, lidars, and radars. Zonal mean latitudinal variation of S5P cloud properties is similar to that of other satellite data. S5P OCRA/ROCINN_CAL agrees well with NPP VIIRS cloud-top height and cloud optical thickness and with Cloudnet cloud-top height, especially for the low (mostly liquid) clouds. For the high clouds, S5P OCRA/ROCINN_CAL cloud-top height is below the cloud-top height of VIIRS and of Cloudnet, while its cloud optical thickness is higher than that of VIIRS. S5P OCRA/ROCINN_CRB and S5P FRESCO cloud height are well below the Cloudnet cloud mean height for the low clouds but match on average better with the Cloudnet cloud mean height for the higher clouds. As opposed to S5P OCRA/ROCINN_CRB and S5P FRESCO, S5P OCRA/ROCINN_CAL is well able to match the lowest CTH mode of the Cloudnet observations. Peculiar geographical patterns are identified in the cloud products and will be mitigated in future releases of the cloud data products.

Published
2021

21. Validation of the Sentinel-5 Precursor TROPOMI cloud data withCloudnet, Aura OMI O2–O2, MODIS, and Suomi-NPP VIIR

Author

Compernolle, Steven, Argyrouli, Athina, Lutz, Ronny, Sneep, Maarten, Lambert, Jean-Christopher, Fjæraa, Ann Mari, Hubert, Daan, Keppens, Arno, Loyola, Diego, O'Connor, Ewan, Romahn, Fabian, Stammes, Piet, Verhoelst, Tijl, and Wang, Ping

Abstract

Accurate knowledge of cloud properties is essential to the measurement of atmospheric composition from space. In this work we assess the quality of the cloud data from three Copernicus Sentinel-5 Precursor (S5P) TROPOMI cloud products: (i) S5P OCRA/ROCINN_CAL (Optical Cloud Recognition Algorithm/Retrieval of Cloud Information using Neural Networks;Clouds-As-Layers), (ii) S5P OCRA/ROCINN_CRB (Clouds-as-Reflecting Boundaries), and (iii) S5P FRESCO-S (Fast Retrieval Scheme for Clouds from Oxygen absorption bands – Sentinel). Target properties of this work are cloud-top height and cloud optical thickness (OCRA/ROCINN_CAL), cloud height (OCRA/ROCINN_CRB and FRESCO-S), and radiometric cloud fraction (all three algorithms). The analysis combines (i) the examination of cloud maps for artificial geographical patterns, (ii) the comparison to other satellite cloud data (MODIS, NPP-VIIRS, and OMI O2–O2), and (iii) ground-based validation with respect to correlative observations (30 April 2018 to 27 February 2020) from the Cloudnet network of ceilometers, lidars, and radars. Zonal mean latitudinal variation of S5P cloud properties is similar to that of other satellite data. S5P OCRA/ROCINN_CAL agrees well with NPP VIIRS cloud-top height and cloud optical thickness and with Cloudnet cloud-top height, especially for the low (mostly liquid) clouds. For the high clouds, S5P OCRA/ROCINN_CAL cloud-top height is below the cloud-top height of VIIRS and of Cloudnet, while its cloud optical thickness is higher than that of VIIRS. S5P OCRA/ROCINN_CRB and S5P FRESCO cloud height are well below the Cloudnet cloud mean height for the low clouds but match on average better with the Cloudnet cloud mean height for the higher clouds. As opposed to S5P OCRA/ROCINN_CRB and S5P FRESCO, S5P OCRA/ROCINN_CAL is well able to match the lowest CTH mode of the Cloudnet observations. Peculiar geographical patterns are identified in the cloud products and will be mitigated in future releases of the cloud data products.

Published
2021

22. S5P TROPOMI NO2 slant column retrieval: method, stability, uncertainties and comparisons with OMI

Author

Van Geffen, Jos, Boersma, K.F., Eskes, Henk, Sneep, Maarten, Ter Linden, Mark, Zara, Marina, and Pepijn Veefkind, J.

Subjects
Meteorologie en Luchtkwaliteit, WIMEK, Meteorology and Air Quality, Life Science
Abstract

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 7×3.5 km2 (approx. 5.5×3.5 km2 as of 6 August 2019), achieving near-global coverage in 1 d. The retrieval of nitrogen dioxide (NO2) 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 NO2 SCD retrieval: the retrieval method used, the stability of the SCDs and the SCD uncertainties, and a comparison with the Ozone Monitoring Instrument (OMI) NO2 SCDs. The statistical uncertainty, based on the spatial variability of the SCDs over a remote Pacific Ocean sector, is 8.63 µmol m−2 for all pixels (9.45 µmol m−2 for clear-sky pixels), which is very stable over time and some 30 % less than the long-term average over OMI–QA4ECV data (since the pixel size reduction TROPOMI uncertainties are ∼8 % larger). The SCD uncertainty reported by the differential optical absorption spectroscopy (DOAS) fit is about 10 % larger than the statistical uncertainty, while for OMI–QA4ECV the DOAS uncertainty is some 20 % larger than its statistical uncertainty. Comparison of the SCDs themselves over the Pacific Ocean, averaged over 1 month, shows that TROPOMI is about 5 % 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 % higher SCDs. The row-to-row variation in the SCDs of TROPOMI, the “stripe amplitude”, is 2.15 µmol m−2, while for OMI–QA4ECV it is a factor of ∼2 (∼5) 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. The TROPOMI data used in this study cover 30 April 2018 up to 31 January 2020.

Published
2020

23. S5P TROPOMI NO2 slant column retrieval : Method, stability, uncertainties and comparisons with OMI

Author

Geffen, Jos, Van, Boersma, K.F., Eskes, Henk, Sneep, Maarten, Linden, Mark, Ter, Zara, Marina, Pepijn Veefkind, J., Geffen, Jos, Van, Boersma, K.F., Eskes, Henk, Sneep, Maarten, Linden, Mark, Ter, Zara, Marina, and Pepijn Veefkind, J.

Abstract

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 7 × 3:5 km2 (approx. 5:5 × 3:5 km2 as of 6 August 2019), achieving near-global coverage in 1 d. The retrieval of nitrogen dioxide (NO2) 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 NO2 SCD retrieval: the retrieval method used, the stability of the SCDs and the SCD uncertainties, and a comparison with the Ozone Monitoring Instrument (OMI) NO2 SCDs. The statistical uncertainty, based on the spatial variability of the SCDs over a remote Pacific Ocean sector, is 8.63 μmol m-2 for all pixels (9.45 μmol m-2 for clear-sky pixels), which is very stable over time and some 30 % less than the long-term average over OMI-QA4ECV data (since the pixel size reduction TROPOMI uncertainties are ~ 8 % larger). The SCD uncertainty reported by the differential optical absorption spectroscopy (DOAS) fit is about 10 % larger than the statistical uncertainty, while for OMI-QA4ECV the DOAS uncertainty is some 20 % larger than its statistical uncertainty. Comparison of the SCDs themselves over the Pacific Ocean, averaged over 1 month, shows that TROPOMI is about 5 % 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 % higher SCDs. The row-torow variation in the SCDs of TROPOMI, the "stripe amplitude", is 2.15 μmol m, while for OMI-QA4ECV it is a factor of ~ 2 (~ 5) larger in 2005 (2018); still, a so-called stripe correction

Published
2020

24. S5P TROPOMI NO2 slant column retrieval: Method, stability, uncertainties and comparisons with OMI

Author

Van Geffen, Jos (author), Folkert Boersma, K. (author), Eskes, Henk (author), Sneep, Maarten (author), Ter Linden, Mark (author), Zara, Marina (author), Veefkind, j. Pepijn (author), Van Geffen, Jos (author), Folkert Boersma, K. (author), Eskes, Henk (author), Sneep, Maarten (author), Ter Linden, Mark (author), Zara, Marina (author), and Veefkind, j. Pepijn (author)

Abstract

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 7 × 3:5 km2 (approx. 5:5 × 3:5 km2 as of 6 August 2019), achieving near-global coverage in 1 d. The retrieval of nitrogen dioxide (NO2) 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 NO2 SCD retrieval: the retrieval method used, the stability of the SCDs and the SCD uncertainties, and a comparison with the Ozone Monitoring Instrument (OMI) NO2 SCDs. The statistical uncertainty, based on the spatial variability of the SCDs over a remote Pacific Ocean sector, is 8.63 μmol m-2 for all pixels (9.45 μmol m-2 for clear-sky pixels), which is very stable over time and some 30 % less than the long-term average over OMI-QA4ECV data (since the pixel size reduction TROPOMI uncertainties are ~ 8 % larger). The SCD uncertainty reported by the differential optical absorption spectroscopy (DOAS) fit is about 10 % larger than the statistical uncertainty, while for OMI-QA4ECV the DOAS uncertainty is some 20 % larger than its statistical uncertainty. Comparison of the SCDs themselves over the Pacific Ocean, averaged over 1 month, shows that TROPOMI is about 5 % 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 % higher SCDs. The row-torow variation in the SCDs of TROPOMI, the "stripe amplitude", is 2.15 μmol m, while for OMI-QA4ECV it is a factor of ~ 2 (~ 5) larger in 2005 (2018); still, a so-called stripe correction, Atmospheric Remote Sensing

Published
2020
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25. A first comparison of TROPOMI aerosol layer height (ALH) to CALIOP data

Author

Nanda, S. (author), de Graaf, M. (author), Veefkind, j. Pepijn (author), Sneep, Maarten (author), Sun, J. (author), Levelt, Pieternel Felicitas (author), Nanda, S. (author), de Graaf, M. (author), Veefkind, j. Pepijn (author), Sneep, Maarten (author), Sun, J. (author), and Levelt, Pieternel Felicitas (author)

Abstract

The TROPOspheric Monitoring Instrument (TROPOMI) level-2 aerosol layer height (ALH) product has now been released to the general public. This product is retrieved using TROPOMI's measurements of the oxygen A-band, radiative transfer model (RTM) calculations augmented by neural networks and an iterative optimal estimation technique. The TROPOMI ALH product will deliver ALH estimates over cloud-free scenes over the ocean and land that contain aerosols above a certain threshold of the measured UV aerosol index (UVAI) in the ultraviolet region. This paper provides background for the ALH product and explores its quality by comparing ALH estimates to similar quantities derived from spaceborne lidars observing the same scene. The spaceborne lidar chosen for this study is the Cloud-Aerosol LIdar with Orthogonal Polarization (CALIOP) on the Cloud-Aerosol Lidar and Infrared Pathfinder Satellite Observation (CALIPSO) mission, which flies in formation with NASA's A-train constellation since 2006 and is a proven source of data for studying ALHs. The influence of the surface and clouds is discussed, and the aspects of the TROPOMI ALH algorithm that will require future development efforts are highlighted. A case-by-case analysis of the data from the four selected cases (mostly around the Saharan region with approximately 800 co-located TROPOMI pixels and CALIOP profiles in June and December 2018) shows that ALHs retrieved from TROPOMI using the operational Sentinel-5 Precursor Level-2 ALH algorithm is lower than CALIOP aerosol extinction heights by approximately 0.5km. Looking at data beyond these cases, it is clear that there is a significant difference when it comes to retrievals over land, where these differences can easily go over 1km on average., Atmospheric Remote Sensing

Published
2020
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26. Validation of the Sentinel-5 Precursor TROPOMI cloud data with Cloudnet, Aura OMI O&lt;sub&gt;2&lt;/sub&gt;–O&lt;sub&gt;2&lt;/sub&gt;, MODIS, and Suomi-NPP VIIRS

Author

Compernolle, Steven, primary, Argyrouli, Athina, additional, Lutz, Ronny, additional, Sneep, Maarten, additional, Lambert, Jean-Christopher, additional, Fjæraa, Ann Mari, additional, Hubert, Daan, additional, Keppens, Arno, additional, Loyola, Diego, additional, O'Connor, Ewan, additional, Romahn, Fabian, additional, Stammes, Piet, additional, Verhoelst, Tijl, additional, and Wang, Ping, additional

Published
2021
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27. Validation of Sentinel-5p TROPOMI cloud data with ground-based Cloudnet and other satellite data products

Author

Compernolle, Steven, primary, Argyrouli, Athina, additional, Lutz, Ronny, additional, Sneep, Maarten, additional, Lambert, Jean-Christopher, additional, Fjaeraa, Ann Mari, additional, Granville, José, additional, Hubert, Daan, additional, Keppens, Arno, additional, Loyola, Diego, additional, O'Connor, Ewan, additional, Rasson, Olivier, additional, Romahn, Fabian, additional, Stammes, Piet, additional, Verhoelst, Tijl, additional, and Wang, Ping, additional

Published
2021
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29. Intercomparison of Cloud Products based on S5P/TROPOMI Level 1b Data Version 1 and the updated Version 2

Author

Latsch, Miriam, primary, Richter, Andreas, additional, Burrows, John P., additional, Wagner, Thomas, additional, Sihler, Holger, additional, van Roozendael, Michel, additional, Loyola, Diego, additional, Valks, Pieter, additional, Argyrouli, Athina, additional, Lutz, Ronny, additional, Veefkind, Pepijn, additional, Eskes, Henk, additional, Sneep, Maarten, additional, Wang, Ping, additional, and Siddans, Richard, additional

Published
2021
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31. Effects of clouds on the UV Absorbing Aerosol Index from TROPOMI

Author

Kooreman, Maurits L., primary, Stammes, Piet, additional, Trees, Victor, additional, Sneep, Maarten, additional, Tilstra, L. Gijsbert, additional, de Graaf, Martin, additional, Stein Zweers, Deborah C., additional, Wang, Ping, additional, Tuinder, Olaf N. E., additional, and Veefkind, J. Pepijn, additional

Published
2020
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32. Supplementary material to "Validation of the Sentinel-5 Precursor TROPOMI cloud data with Cloudnet, Aura OMI O2-O2, MODIS and Suomi-NPP VIIRS"

Author

Compernolle, Steven, primary, Argyrouli, Athina, additional, Lutz, Ronny, additional, Sneep, Maarten, additional, Lambert, Jean-Christopher, additional, Fjæraa, Ann Mari, additional, Hubert, Daan, additional, Keppens, Arno, additional, Loyola, Diego, additional, O'Connor, Ewan, additional, Romahn, Fabian, additional, Stammes, Piet, additional, Verhoelst, Tijl, additional, and Wang, Ping, additional

Published
2020
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33. Validation of the Sentinel-5 Precursor TROPOMI cloud data with Cloudnet, Aura OMI O&lt;sub&gt;2&lt;/sub&gt;-O&lt;sub&gt;2&lt;/sub&gt;, MODIS and Suomi-NPP VIIRS

Author

Compernolle, Steven, primary, Argyrouli, Athina, additional, Lutz, Ronny, additional, Sneep, Maarten, additional, Lambert, Jean-Christopher, additional, Fjæraa, Ann Mari, additional, Hubert, Daan, additional, Keppens, Arno, additional, Loyola, Diego, additional, O'Connor, Ewan, additional, Romahn, Fabian, additional, Stammes, Piet, additional, Verhoelst, Tijl, additional, and Wang, Ping, additional

Published
2020
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35. Validation of Sentinel-5p retrieved cloud height data using ground-based radar/lidar measurements from the CLOUDNET network

Author

Compernolle, Steven, primary, Argyrouli, Athina, additional, Lutz, Ronny, additional, Sneep, Maarten, additional, Granville, José, additional, Hubert, Daan, additional, Keppens, Arno, additional, Verhoelst, Tijl, additional, Fjaeraa, Ann Mari, additional, Loyola, Diego, additional, O'Connor, Ewan, additional, and Lambert, Jean-Christopher, additional

Published
2020
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37. Evaluation of TROPOMI cloud products for NO2 retrievals

Author

Latsch, Miriam, primary, Richter, Andreas, additional, Burrows, John P., additional, Wagner, Thomas, additional, Silher, Holger, additional, van Roozendael, Michel, additional, Loyola, Diego, additional, Valks, Pieter, additional, Argyrouli, Athina, additional, Lutz, Ronny, additional, Veefkind, Pepijn, additional, Eskes, Henk, additional, Sneep, Maarten, additional, Wang, Ping, additional, and Siddans, Richard, additional

Published
2020
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39. Fast Simulators for Satellite Cloud Optical Centroid Pressure Retrievals, 1. Evaluation of OMI Cloud Retrievals

Author

Joiner, J, Vasilkov, A. P, Gupta, Pawan, Bhartia, P. K, Veefkind, Pepijn, Sneep, Maarten, deHaan, Johan, Polonsky, Igor, and Spurr, Robert

Subjects
Meteorology And Climatology
Abstract

We have developed a relatively simple scheme for simulating retrieved cloud optical centroid pressures (OCP) from satellite solar backscatter observations. We have compared simulator results with those from more detailed retrieval simulators that more fully account for the complex radiative transfer in a cloudy atmosphere. We used this fast simulator to conduct a comprehensive evaluation of cloud OCPs from the two OMI algorithms using collocated data from CloudSat and Aqua MODIS, a unique situation afforded by the A-train formation of satellites. We find that both OMI algorithms perform reasonably well and that the two algorithms agree better with each other than either does with the collocated CloudSat data. This indicates that patchy snow/ice, cloud 3D, and aerosol effects not simulated with the CloudSat data are affecting both algorithms similarly. We note that the collocation with CloudSat occurs mainly on the East side of OMI's swath. Therefore, we are not able to address cross-track biases in OMI cloud OCP retrievals. Our fast simulator may also be used to simulate cloud OCP from output generated by general circulation models (GCM) with appropriate account of cloud overlap. We have implemented such a scheme and plan to compare OMI data with GCM output in the near future.

Published
2011

41. S5P/TROPOMI NO2 slant column retrieval: method, stability, uncertainties, and comparisons against OMI

Author

Geffen, Jos, Boersma, K. Folkert, Eskes, Henk, Sneep, Maarten, Linden, Mark, Zara, Marina, and Veefkind, J. Pepijn

Abstract

The Tropospheric Monitoring Instrument (TROPOMI), aboard the Sentinel-5 Precursor (S5P) satellite, launched on 13 Oct. 2017, provides measurements of atmospheric trace gases and of cloud and aerosol properties on an unprecedented spatial resolution of approximately 7 × 3.5 km2 (approx. 5.5 × 3.5 km2 as of 6 Aug. 2019), achieving near-global coverage in one day. The retrieval of nitrogen dioxide (NO2) concentrations is a 3-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 NO2 SCD retrieval: the retrieval method used, the stability of the SCDs and the SCD uncertainties, and a comparison against OMI NO2 SCDs. The statistical uncertainty, based on the spatial variability of the SCDs over a remote Pacific Ocean sector, is 8.63 μmol/m2 for all pixels (9.45 μmol/m2 for cloud-free pixels), which is very stable over time and some 30 % less than the long-term average over OMI/QA4ECV data (since the pixel size reduction TROPOMI uncertainties are ∼ 10 % larger). The SCD uncertainty reported by the DOAS fit is about 10 % larger than the statistical uncertainty, while for OMI/QA4ECV the DOAS uncertainty is some 20 % larger than its statistical uncertainty. Comparison of the SCDs themselves over the Pacific Ocean, averaged over one month, shows that TROPOMI is about 5 % 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 % higher SCDs. The row-to-row variation in the SCDs of TROPOMI, the stripe amplitude, is 2.14 μmol/m2, while for OMI/QA4ECV it is ∼ 2 (∼ 5) 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 against OMI/QA4ECV and operates as anticipated from instrument specifications. The TROPOMI data used in this study covers 30 April 2018 up to 31 Oct. 2019.

Published
2019

42. Ground-based Assessment of the First Year of Sentinel-5p Tropospheric Ozone Data

Author

Hubert, Daan, Keppen, Arno, Verhoelst, Tijl, Granville, José, Lambert, Jean-Christopher, Heue, Klaus-Peter, Pedergnana, Mattia, Loyola, Diego, Eichmann, Kai-Uwe, Weber, Mark, Apituley, Arnoud, Sneep, Maarten, Tuinder, Olaf, Veefkind, Pepijn, Thompson, Anne, Witte, Jacquelyn, Johnson, Bryan, Vömel, Holger, Selkirk, Henry, Piters, Ankie, Da Silva, Francisco, Mohamad, Maznorizan, Félix, Christian, Ancellet, Gérard, Delcloo, Andy, Duflot, Valentin, Godin-Beekmann, Sophie, Leblanc, Thierry, Steinbrecht, Wolfgang, Stübi, René, Belgian Institute for Space Aeronomy / Institut d'Aéronomie Spatiale de Belgique (BIRA-IASB), DLR Institut für Methodik der Fernerkundung / DLR Remote Sensing Technology Institute (IMF), Deutsches Zentrum für Luft- und Raumfahrt [Oberpfaffenhofen-Wessling] (DLR), Institut für Umweltphysik [Bremen] (IUP), Universität Bremen, Royal Netherlands Meteorological Institute (KNMI), NASA Goddard Space Flight Center (GSFC), Science Systems and Applications, Inc. [Lanham] (SSAI), NOAA Earth System Research Laboratory (ESRL), National Oceanic and Atmospheric Administration (NOAA), National Center for Atmospheric Research [Boulder] (NCAR), Universities Space Research Association (USRA), Laboratory of Environmental and Tropical Variables [Natal], Instituto Nacional de Pesquisas Espaciais (INPE), Malaysian Meteorological Department (MetMalaysia), Ministry of Science, Technology and Innovation [Malaysia] (MOSTI), Federal Office of Meteorology and Climatology MeteoSwiss, TROPO - LATMOS, Laboratoire Atmosphères, Milieux, Observations Spatiales (LATMOS), Sorbonne Université (SU)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Sorbonne Université (SU)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS), Institut Royal Météorologique de Belgique [Bruxelles] (IRM), Laboratoire de l'Atmosphère et des Cyclones (LACy), Centre National de la Recherche Scientifique (CNRS)-Université de La Réunion (UR)-Institut national des sciences de l'Univers (INSU - CNRS)-Météo France, STRATO - LATMOS, Jet Propulsion Laboratory (JPL), California Institute of Technology (CALTECH)-NASA, Meteorologisches Observatorium Hohenpeißenberg (MOHp), Deutscher Wetterdienst [Offenbach] (DWD), and Cardon, Catherine

Subjects
[PHYS.PHYS.PHYS-AO-PH]Physics [physics]/Physics [physics]/Atmospheric and Oceanic Physics [physics.ao-ph], [SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere, [SDU.OCEAN] Sciences of the Universe [physics]/Ocean, Atmosphere, [PHYS.PHYS.PHYS-AO-PH] Physics [physics]/Physics [physics]/Atmospheric and Oceanic Physics [physics.ao-ph]
Abstract

International audience; Tropospheric ozone is a pollutant that damages ecosystems and triggers human health problems. Ozone concentrations are highly variable over time and across the troposphere, which poses clear challenges to deepen our understanding of the processes involved in the production and transport of ozone. Further progress depends on the availability of instruments capable of measuring tropospheric ozone and its distribution at finer spatio-temporal scales. The TROPOMI instrument on the Sentinel-5p platform, launched into an early afternoon polar orbit in October 2017, combines a high spatial resolution, a large swath width and the spectral measurement characteristics required to deliver tropospheric ozone data records at unprecedented detail. The first of these products was released during Fall 2018. It consists in 0.5° (latitude) by 1° (longitude) resolved daily maps of 3-day moving mean values of the tropospheric ozone column between 20°S and 20°N, and it is computed using the convective-cloud method (CCD). A second data product consists in maps of tropical upper tropospheric ozone mixing ratio at a coarser spatial and temporal resolution. It is based on a cloud slicing algorithm (CSA), which is currently being fine-tuned for release in the very near future. A third data product, also under development at the time of this abstract, consists of the vertical profile of ozone concentration in the global troposphere and stratosphere, retrieved with the classical Optimal Estimation (OE) technique. We present here an assessment of the quality of the first year of the different tropospheric ozone column data sets retrieved from Sentinel-5p TROPOMI measurements, carried out within the context of ESA’s Sentinel-5p Mission Performance Center (MPC) and the S5PVT AO project CHEOPS-5p (Validation of Copernicus Height-resolved Ozone data Products from Sentinel-5p TROPOMI using global sonde and lidar networks, #28587). The first stage of this analysis consists of an inspection of the tropospheric ozone fields for structures which are potentially introduced in the measurement process. Sampling effects, in particular, are a possible source of uncertainty as the CCD product is derived from binned TROPOMI total ozone column data. Another structure introduced by retrieval assumptions would be the dependence of the quality of Sentinel-5p retrieved total column data to cloud parameters. In a second stage the satellite data are confronted to quality-assured ozonesonde and –tentatively– ground-based lidar measurements from the NDACC, SHADOZ and TOLNET networks. These well-characterized observational data records serve as a reference to evaluate the bias and uncertainty of the Sentinel-5p data, and their dependence on influence quantities. The study concludes with an assessment of the compliance of Sentinel-5p tropospheric ozone data with respect to mission and user requirements for key data applications.

Published
2019

43. A Sample of What We Have Learned from A-Train Cloud Measurements

Author

Joiner, Joanna, Vasilkov, Alexander, Ziemke, Jerry, Chandra, Sushil, Spurr, Robert, Bhartia, P. K, Krotkov, Nick, Sneep, Maarten, Menzel, Paul, Platnick, Steve, Stephens, Graeme, Wennberg, Paul, Avery, Melody, Wentz, Frank, Vanbaunce, Claudine, Pilewski, Peter, Diskin, Glenn, and Vay, Stephanie

Subjects
Meteorology And Climatology
Abstract

The A-train active sensors CloudSat and CALIPSO provide detailed information about cloud vertical structure. Coarse vertical information can also be obtained from a combination of passive sensors (e.g. cloud liquid water content from AMSR-E, cloud ice properties from MLS and HIRDLS, cloud-top pressure from MODIS and AIRS, and UVNISINear IR absorption and scattering from OMI, MODIS, and POLDER). In addition, the wide swaths of instruments such as MODIS, AIRS, OMI, POLDER, and AMSR-E can be exploited to create estimates of the three-dimensional cloud extent. We will show how data fusion from A-train sensors can be used, e.g., to detect and map the presence of multiple layer/phase clouds. Ultimately, combined cloud information from Atrain instruments will allow for estimates of heating and radiative flux at the surface as well as UV/VIS/Near IR trace-gas absorption at the overpass time on a near-global daily basis. CloudSat has also dramatically improved our interpretation of visible and UV passive measurements in complex cloudy situations such as deep convection and multiple cloud layers. This has led to new approaches for unique and accurate constituent retrievals from A-train instruments. For example, ozone mixing ratios inside tropical deep convective clouds have recently been estimated using the Aura Ozone Monitoring Instrument (OMI). Field campaign data from TC4 provide additional information about the spatial variability and origin of trace-gases inside convective clouds. We will highlight some of the new applications of remote sensing in cloudy conditions that have been enabled by the synergy between the A-train active and passive sensors.

Published
2008

45. A neural network radiative transfer model approach applied to the Tropospheric Monitoring Instrument aerosol height algorithm

Author

Nanda, Swadhin (author), De Graaf, Martin (author), Veefkind, j. Pepijn (author), Ter Linden, Mark (author), Sneep, Maarten (author), De Haan, Johan (author), Levelt, Pieternel Felicitas (author), Nanda, Swadhin (author), De Graaf, Martin (author), Veefkind, j. Pepijn (author), Ter Linden, Mark (author), Sneep, Maarten (author), De Haan, Johan (author), and Levelt, Pieternel Felicitas (author)

Abstract

To retrieve aerosol properties from satellite measurements of the oxygen A-band in the near-infrared, a line-by-line radiative transfer model implementation requires a large number of calculations. These calculations severely restrict a retrieval algorithm's operational capability as it can take several minutes to retrieve the aerosol layer height for a single ground pixel. This paper proposes a forward modelling approach using artificial neural networks to speed up the retrieval algorithm. The forward model outputs are trained into a set of neural network models to completely replace line-by-line calculations in the operational processor. Results comparing the forward model to the neural network alternative show an encouraging outcome with good agreement between the two when they are applied to retrieval scenarios using both synthetic and real measured spectra from TROPOMI (TROPOspheric Monitoring Instrument) on board the European Space Agency (ESA) Sentinel-5 Precursor mission. With an enhancement of the computational speed by 3 orders of magnitude, TROPOMI's operational aerosol layer height processor is now able to retrieve aerosol layer heights well within operational capacity., Atmospheric Remote Sensing

Published
2019
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46. High-Resolution Mapping of Nitrogen Dioxide With TROPOMI : First Results and Validation Over the Canadian Oil Sands

Author

Griffin, Debora, Zhao, Xiaoyi, McLinden, Chris A., Boersma, Folkert, Bourassa, Adam, Dammers, Enrico, Degenstein, Doug, Eskes, Henk, Fehr, Lukas, Fioletov, Vitali, Hayden, Katherine, Kharol, Shailesh K., Li, Shao Meng, Makar, Paul, Martin, Randall V., Mihele, Cristian, Mittermeier, Richard L., Krotkov, Nickolay, Sneep, Maarten, Lamsal, Lok N., ter Linden, Mark, van Geffen, Jos, Veefkind, Pepijn, Wolde, Mengistu, Griffin, Debora, Zhao, Xiaoyi, McLinden, Chris A., Boersma, Folkert, Bourassa, Adam, Dammers, Enrico, Degenstein, Doug, Eskes, Henk, Fehr, Lukas, Fioletov, Vitali, Hayden, Katherine, Kharol, Shailesh K., Li, Shao Meng, Makar, Paul, Martin, Randall V., Mihele, Cristian, Mittermeier, Richard L., Krotkov, Nickolay, Sneep, Maarten, Lamsal, Lok N., ter Linden, Mark, van Geffen, Jos, Veefkind, Pepijn, and Wolde, Mengistu

Abstract

TROPOspheric Monitoring Instrument (TROPOMI), on-board the Sentinel-5 Precurser satellite, is a nadir-viewing spectrometer measuring reflected sunlight in the ultraviolet, visible, near-infrared, and shortwave infrared. From these spectra several important air quality and climate-related atmospheric constituents are retrieved, including nitrogen dioxide (NO2) at unprecedented spatial resolution from a satellite platform. We present the first retrievals of TROPOMI NO2 over the Canadian Oil Sands, contrasting them with observations from the Ozone Monitoring Instrument satellite instrument, and demonstrate TROPOMI's ability to resolve individual plumes and highlight its potential for deriving emissions from individual mining facilities. Further, the first TROPOMI NO2 validation is presented, consisting of aircraft and surface in situ NO2 observations, and ground-based remote-sensing measurements between March and May 2018. Our comparisons show that the TROPOMI NO2 vertical column densities are highly correlated with the aircraft and surface in situ NO2 observations, and the ground-based remote-sensing measurements with a low bias (15–30 %); this bias can be reduced by improved air mass factors.

Published
2019

47. Sentinel-5P TROPOMI NO2 retrieval: impact of version v2.2 improvements and comparisons with OMI and ground-based data.

Author

van Geffen, Jos, Eskes, Henk, Compernolle, Steven, Pinardi, Gaia, Verhoelst, Tijl, Lambert, Jean-Christopher, Sneep, Maarten, ter Linden, Mark, Ludewig, Antje, Boersma, K. Folkert, and Veefkind, J. Pepijn

Subjects
ALBEDO, SPATIAL resolution, ICE clouds, INFORMATION resources, TROPOSPHERIC aerosols, NITROGEN dioxide, SIGNAL-to-noise ratio, CLIMATOLOGY
Abstract

Nitrogen dioxide (NO2) is one of the main data products measured by the Tropospheric Monitoring Instrument (TROPOMI) on the Sentinel-5 Precursor (S5P) satellite, which combines a high signal-to-noise ratio with daily global coverage and high spatial resolution. TROPOMI provides a valuable source of information to monitor emissions from local sources such as power plants, industry, cities, traffic and ships, and variability of these sources in time. Validation exercises of NO2 version v1.2-v1.3 data, however, have revealed that TROPOMI's tropospheric vertical columns (VCDs) are too low by up to 50 % over highly polluted areas. These findings are mainly attributed to biases in the cloud pressure retrieval, the surface albedo climatology and the low resolution of the a-priori profiles derived from global simulations of the TM5-MP chemistry model. This study describes improvements in the TROPOMI NO2 retrieval leading to version v2.2, operational since 1 July 2021. Compared to v1.x, the main changes are: (1) The NO2-v2.2 data is based on version 2 level-1B (ir)radiance spectra with improved calibration, which results in a small and fairly homogeneous increase of the NO2 slant columns of 3 to 4 %, most of which ends up as a small increase of the stratospheric columns; (2) The cloud pressures are derived with a new version of the FRESCO cloud retrieval already introduced in NO2-v1.4, which lead to a lowering of the cloud pressure, resulting in larger tropospheric NO2 columns over polluted scenes with a small but non- zero cloud coverage; (3) For cloud-free scenes a surface albedo correction is introduced based on the observed reflectance, which also leads to a general increase of the tropospheric NO2 columns over polluted scenes of order 15 %; (4) An outlier removal was implemented in the spectral fit, which increases the number of good quality retrievals over the South-Atlantic Anomaly region and over bright clouds where saturation may occur; (5) Snow-Ice information is now obtained from ECMWF weather data, increasing the number of valid retrievals at high latitudes. On average the NO2-v2.2 data have tropospheric VCDs that are between 10 and 40 % larger than the v1.x data, depending on the level of pollution and season; the largest impact is found at mid- and high- latitudes in wintertime. This has brought these tropospheric NO2 closer to OMI observations. Ground-based validation shows on average an improvement of the negative bias of the stratospheric (from -6 % to -3 %), tropospheric (from -32 % to -23 %) and total (from -12 % to -5 %) columns. For individual measurement stations, however, the picture is more complicated, in particular for the tropospheric and total columns. [ABSTRACT FROM AUTHOR]

Published
2021
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48. Improved monitoring of shipping NO2 with TROPOMI: decreasing NOx emissions in European seas during the COVID-19 pandemic.

Author

Riess, T. Christoph V. W., Boersma, K. Folkert, vanVliet, Jasper, Peters, Wouter, Sneep, Maarten, Eskes, Henk, and van Geffen, Jos

Subjects
COVID-19 pandemic, EMISSIONS (Air pollution), SPATIAL resolution, ARTIFICIAL neural networks, MARITIME shipping, TROPOSPHERIC aerosols
Abstract

TROPOMI measurements of tropospheric NO2 columns provide powerful information on emissions of air pollution by ships on open sea. This information is potentially useful for authorities to help determine the (non-)compliance of ships with increasingly stringent NOx emission regulations. We find that the information quality is improved further by recent upgrades in the TROPOMI cloud retrieval and an optimal data selection. We show that the superior spatial resolution of TROPOMI allows the detection of several lanes of NO2 pollution ranging from the Aegean Sea near Greece to the Skagerrak in Scandinavia, which have not been detected with other satellite instruments before. Additionally, we demonstrate that under conditions of sun glint TROPOMI's vertical sensitivity to NO2 in the marine boundary layer increases by up to 60 %. The benefits of sun glint are most prominent under clear-sky situations when sea surface winds are low, but slightly above zero (±2 m/s). Beyond spatial resolution and sun glint, we examine for the first time the impact of the recently improved cloud algorithm on the TROPOMI NO2 retrieval quality, both over sea and over land. We find that the new FRESCO+wide algorithm leads to 50 hPa lower cloud pressures, correcting a known high bias, and produces 1-4·1015 molec/cm2 higher retrieved NO2 columns, thereby at least partially correcting for the previously reported low bias in the TROPOMI NO2 product. By training an artificial neural network on the 4 available periods with standard and FRESCO+wide test-retrievals, we develop a historic, consistent TROPOMI NO2 data set spanning the years 2019 and 2020. This improved data set shows stronger (35-75 %) and sharper (10-35 %) shipping NO2 signals compared to co-sampled measurements from OMI. We apply our improved data set to investigate the impact of the COVID-19 pandemic on ship NO2 pollution over European seas and find indications that NOx emissions from ships reduced by 20-25 % during the pandemic. The reductions in ship NO2 pollution start in March-April 2020, in line with changes in shipping activity inferred from AIS data. [ABSTRACT FROM AUTHOR]

Published
2021
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49. The Operational Sentinel-5 Precursor Geophysical Products and Perspectives for Sentinel-4

Author

Loyola, Diego, Veefkind, Pepijn, Landgraf, Jochen, Van Roozendael, Michel, Richter, Andreas, Siddans, Richard, Wagner, Thomas, Tamminen, J., Aben, Ilse, Lambert, Jean-Christopher, Heue, Klaus-Peter, Lerot, Christophe, Zimmer, Walter, Romahn, Fabian, Balis, Dimitris, Verhoelst, Tijl, Koukouli, MariLiza, Garane, Katerina, ter Linden, Mark, Keppens, Arno, Tuinder, O., Pedergnana, Mattia, Hubert, Daan, Eskes, Henk, Eichmann, Kai-Uwe, Compernolle, Steven, Valks, Pieter, Theys, Nicolas, Hedelt, Pascal, De Smedt, Isabelle, Chan, Ka Lok, Borsdorff, Tobias, Langerock, B., Hu, Haili, Argyrouli, Athina, Sneep, Maarten, Lutz, Ronny, Wang, Ping, Stein Zweers, Deborah, de Graaf, Martin, Smith, Andy, Kujanpää, J., Huan, Yu, Cheng, Zhibin, Dehn, Angelika, and Zehner, Claus

Subjects
Sentinel 5p Overview
Published
2018

50. An overview of the S5P/TROPOMI level 2 file format

Author

Pedergnana, Mattia, Sneep, Maarten, Hedelt, Pascal, Loyola, Diego, ter Linden, Mark, Apituley, Arnoud, and Pepijn, Veefkind

Subjects
LEVEL 2,S5P, TROPOMI, File Format
Published
2018

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