Your search keyword '"Vlemmix, Tim"' showing total 35 results

1. Validation of tropospheric NO2 column measurements of GOME-2A and OMI using MAX-DOAS and direct sun network observations

Author

Pinardi, Gaia, Roozendael, Michel, Hendrick, François, Theys, Nicolas, Abuhassan, Nader, Bais, Alkiviadis, Boersma, Folkert, Cede, Alexander, Chong, Jihyo, Donner, Sebastian, Drosoglou, Theano, Frieß, Udo, Granville, José, Herman, Jay R., Eskes, Henk, Holla, Robert, Hovila, Jari, Irie, Hitoshi, Kanaya, Yugo, Karagkiozidis, Dimitris, Kouremeti, Natalia, Lambert, Jean-Christopher, Ma, Jianzhong, Peters, Enno, Piters, Ankie, Postylyakov, Oleg, Richter, Andreas, Remmers, Julia, Takashima, Hisahiro, Tiefengraber, Martin, Valks, Pieter, Vlemmix, Tim, Wagner, Thomas, and Wittrock, Folkard

Abstract

MAX-DOAS and direct sun NO2 vertical column network data are used to investigate the accuracy of tropospheric NO2 column measurements of the GOME-2 instrument on the MetOP-A satellite platform and the OMI instrument on Aura. The study is based on 23 MAX-DOAS and 16 direct sun instruments at stations distributed worldwide. A method to quantify and correct for horizontal dilution effects in heterogeneous NO2 field conditions is proposed. After systematic application of this correction to urban sites, satellite measurements are found to present smaller biases compared to ground-based reference data in almost all cases. We investigate the seasonal dependence of the validation results, as well as the impact of using different approaches to select satellite ground pixels in coincidence with ground-based data. In optimal comparison conditions (satellite pixels containing the station) the median bias between satellite tropospheric NO2 column measurements and the ensemble of MAX-DOAS and direct sun measurements is found to be significant and equal to −36 % for GOME-2A and −20 % for OMI. These biases are further reduced to −24 % and −8 % respectively, after application of the dilution correction. Comparisons with the QA4ECV satellite product for both GOME-2A and OMI is also performed, showing less scatter but also a slightly larger median tropospheric NO2 column bias with respect to the ensemble of MAX-DOAS and direct sun measurements.

Published

2020

2. Intercomparison of MAX-DOAS vertical profile retrieval algorithms: studies on field data from the CINDI-2 campaign

Author

Tirpitz, Jan-Lukas, primary, Frieß, Udo, additional, Hendrick, François, additional, Alberti, Carlos, additional, Allaart, Marc, additional, Apituley, Arnoud, additional, Bais, Alkis, additional, Beirle, Steffen, additional, Berkhout, Stijn, additional, Bognar, Kristof, additional, Bösch, Tim, additional, Bruchkouski, Ilya, additional, Cede, Alexander, additional, Chan, Ka Lok, additional, den Hoed, Mirjam, additional, Donner, Sebastian, additional, Drosoglou, Theano, additional, Fayt, Caroline, additional, Friedrich, Martina M., additional, Frumau, Arnoud, additional, Gast, Lou, additional, Gielen, Clio, additional, Gomez-Martín, Laura, additional, Hao, Nan, additional, Hensen, Arjan, additional, Henzing, Bas, additional, Hermans, Christian, additional, Jin, Junli, additional, Kreher, Karin, additional, Kuhn, Jonas, additional, Lampel, Johannes, additional, Li, Ang, additional, Liu, Cheng, additional, Liu, Haoran, additional, Ma, Jianzhong, additional, Merlaud, Alexis, additional, Peters, Enno, additional, Pinardi, Gaia, additional, Piters, Ankie, additional, Platt, Ulrich, additional, Puentedura, Olga, additional, Richter, Andreas, additional, Schmitt, Stefan, additional, Spinei, Elena, additional, Stein Zweers, Deborah, additional, Strong, Kimberly, additional, Swart, Daan, additional, Tack, Frederik, additional, Tiefengraber, Martin, additional, van der Hoff, René, additional, van Roozendael, Michel, additional, Vlemmix, Tim, additional, Vonk, Jan, additional, Wagner, Thomas, additional, Wang, Yang, additional, Wang, Zhuoru, additional, Wenig, Mark, additional, Wiegner, Matthias, additional, Wittrock, Folkard, additional, Xie, Pinhua, additional, Xing, Chengzhi, additional, Xu, Jin, additional, Yela, Margarita, additional, Zhang, Chengxin, additional, and Zhao, Xiaoyi, additional

Published

2021

3. Validation of tropospheric NO<sub>2</sub> column measurements of GOME-2A and OMI using MAX-DOAS and direct sun network observations

Author

Pinardi, Gaia, primary, Van Roozendael, Michel, additional, Hendrick, François, additional, Theys, Nicolas, additional, Abuhassan, Nader, additional, Bais, Alkiviadis, additional, Boersma, Folkert, additional, Cede, Alexander, additional, Chong, Jihyo, additional, Donner, Sebastian, additional, Drosoglou, Theano, additional, Dzhola, Anatoly, additional, Eskes, Henk, additional, Frieß, Udo, additional, Granville, José, additional, Herman, Jay R., additional, Holla, Robert, additional, Hovila, Jari, additional, Irie, Hitoshi, additional, Kanaya, Yugo, additional, Karagkiozidis, Dimitris, additional, Kouremeti, Natalia, additional, Lambert, Jean-Christopher, additional, Ma, Jianzhong, additional, Peters, Enno, additional, Piters, Ankie, additional, Postylyakov, Oleg, additional, Richter, Andreas, additional, Remmers, Julia, additional, Takashima, Hisahiro, additional, Tiefengraber, Martin, additional, Valks, Pieter, additional, Vlemmix, Tim, additional, Wagner, Thomas, additional, and Wittrock, Folkard, additional

Published

2020

4. Supplementary material to "Validation of tropospheric NO2 column measurements of GOME-2A and OMI using MAX-DOAS and direct sun network observations"

Author

Pinardi, Gaia, primary, Van Roozendael, Michel, additional, Hendrick, François, additional, Theys, Nicolas, additional, Abuhassan, Nader, additional, Bais, Alkiviadis, additional, Boersma, Folkert, additional, Cede, Alexander, additional, Chong, Jihyo, additional, Donner, Sebastian, additional, Drosoglou, Theano, additional, Frieß, Udo, additional, Granville, José, additional, Herman, Jay R., additional, Eskes, Henk, additional, Holla, Robert, additional, Hovila, Jari, additional, Irie, Hitoshi, additional, Kanaya, Yugo, additional, Karagkiozidis, Dimitris, additional, Kouremeti, Natalia, additional, Lambert, Jean-Christopher, additional, Ma, Jianzhong, additional, Peters, Enno, additional, Piters, Ankie, additional, Postylyakov, Oleg, additional, Richter, Andreas, additional, Remmers, Julia, additional, Takashima, Hisahiro, additional, Tiefengraber, Martin, additional, Valks, Pieter, additional, Vlemmix, Tim, additional, Wagner, Thomas, additional, and Wittrock, Folkard, additional

Published

2020

5. Spaceborne monitoring of CO2 emissions from large cities and the impact of aerosols

Author

Houweling, Sander, primary, Landgraf, Jochen, additional, Reum, Friedemann, additional, van Heck, Hein, additional, Tao, Wei, additional, Cheng, Yafang, additional, Vlemmix, Tim, additional, and Stammes, Piet, additional

Published

2020

6. Comparison of tropospheric NO<sub>2</sub> columns from MAX-DOAS retrievals and regional air quality model simulations

Author

Blechschmidt, Anne-Marlene, primary, Arteta, Joaquim, additional, Coman, Adriana, additional, Curier, Lyana, additional, Eskes, Henk, additional, Foret, Gilles, additional, Gielen, Clio, additional, Hendrick, Francois, additional, Marécal, Virginie, additional, Meleux, Frédérik, additional, Parmentier, Jonathan, additional, Peters, Enno, additional, Pinardi, Gaia, additional, Piters, Ankie J. M., additional, Plu, Matthieu, additional, Richter, Andreas, additional, Segers, Arjo, additional, Sofiev, Mikhail, additional, Valdebenito, Álvaro M., additional, Van Roozendael, Michel, additional, Vira, Julius, additional, Vlemmix, Tim, additional, and Burrows, John P., additional

Published

2020

7. Nitrogen Oxide Emissions from U.S. Oil and Gas Production: Recent Trends and Source Attribution

Author

Dix, Barbara, primary, de Bruin, Joep, additional, Roosenbrand, Esther, additional, Vlemmix, Tim, additional, Francoeur, Colby, additional, Gorchov‐Negron, Alan, additional, McDonald, Brian, additional, Zhizhin, Mikhail, additional, Elvidge, Christopher, additional, Veefkind, Pepijn, additional, Levelt, Pieternel, additional, and de Gouw, Joost, additional

Published

2020

8. Intercomparison of MAX-DOAS vertical profile retrieval algorithms: studies on field data from the CINDI-2 campaign

Author

Tirpitz, Jan-Lukas, primary, Frieß, Udo, additional, Hendrick, François, additional, Alberti, Carlos, additional, Allaart, Marc, additional, Apituley, Arnoud, additional, Bais, Alkis, additional, Beirle, Steffen, additional, Berkhout, Stijn, additional, Bognar, Kristof, additional, Bösch, Tim, additional, Bruchkouski, Ilya, additional, Cede, Alexander, additional, Chan, Ka Lok, additional, den Hoed, Mirjam, additional, Donner, Sebastian, additional, Drosoglou, Theano, additional, Fayt, Caroline, additional, Friedrich, Martina M., additional, Frumau, Arnoud, additional, Gast, Lou, additional, Gielen, Clio, additional, Gomez-Martín, Laura, additional, Hao, Nan, additional, Hensen, Arjen, additional, Henzing, Bas, additional, Hermans, Christian, additional, Jin, Junli, additional, Kreher, Karin, additional, Kuhn, Jonas, additional, Lampel, Johannes, additional, Li, Ang, additional, Liu, Cheng, additional, Liu, Haoran, additional, Ma, Jianzhong, additional, Merlaud, Alexis, additional, Peters, Enno, additional, Pinardi, Gaia, additional, Piters, Ankie, additional, Platt, Ulrich, additional, Puentedura, Olga, additional, Richter, Andreas, additional, Schmitt, Stefan, additional, Spinei, Elena, additional, Stein Zweers, Deborah, additional, Strong, Kimberly, additional, Swart, Daan, additional, Tack, Frederick, additional, Tiefengraber, Martin, additional, van der Hoff, René, additional, van Roozendael, Michel, additional, Vlemmix, Tim, additional, Vonk, Jan, additional, Wagner, Thomas, additional, Wang, Yang, additional, Wang, Zhuoru, additional, Wenig, Mark, additional, Wiegner, Matthias, additional, Wittrock, Folkard, additional, Xie, Pinhua, additional, Xing, Chengzhi, additional, Xu, Jin, additional, Yela, Margarita, additional, Zhang, Chengxin, additional, and Zhao, Xiaoyi, additional

Published

2020

9. Supplementary material to "Intercomparison of MAX-DOAS vertical profile retrieval algorithms: studies on field data from the CINDI-2 campaign"

Author

Tirpitz, Jan-Lukas, primary, Frieß, Udo, additional, Hendrick, François, additional, Alberti, Carlos, additional, Allaart, Marc, additional, Apituley, Arnoud, additional, Bais, Alkis, additional, Beirle, Steffen, additional, Berkhout, Stijn, additional, Bognar, Kristof, additional, Bösch, Tim, additional, Bruchkouski, Ilya, additional, Cede, Alexander, additional, Chan, Ka Lok, additional, den Hoed, Mirjam, additional, Donner, Sebastian, additional, Drosoglou, Theano, additional, Fayt, Caroline, additional, Friedrich, Martina M., additional, Frumau, Arnoud, additional, Gast, Lou, additional, Gielen, Clio, additional, Gomez-Martín, Laura, additional, Hao, Nan, additional, Hensen, Arjen, additional, Henzing, Bas, additional, Hermans, Christian, additional, Jin, Junli, additional, Kreher, Karin, additional, Kuhn, Jonas, additional, Lampel, Johannes, additional, Li, Ang, additional, Liu, Cheng, additional, Liu, Haoran, additional, Ma, Jianzhong, additional, Merlaud, Alexis, additional, Peters, Enno, additional, Pinardi, Gaia, additional, Piters, Ankie, additional, Platt, Ulrich, additional, Puentedura, Olga, additional, Richter, Andreas, additional, Schmitt, Stefan, additional, Spinei, Elena, additional, Stein Zweers, Deborah, additional, Strong, Kimberly, additional, Swart, Daan, additional, Tack, Frederick, additional, Tiefengraber, Martin, additional, van der Hoff, René, additional, van Roozendael, Michel, additional, Vlemmix, Tim, additional, Vonk, Jan, additional, Wagner, Thomas, additional, Wang, Yang, additional, Wang, Zhuoru, additional, Wenig, Mark, additional, Wiegner, Matthias, additional, Wittrock, Folkard, additional, Xie, Pinhua, additional, Xing, Chengzhi, additional, Xu, Jin, additional, Yela, Margarita, additional, Zhang, Chengxin, additional, and Zhao, Xiaoyi, additional

Published

2020

10. An exploratory study on the aerosol height retrieval from OMI measurements of the 477 nm O2 − O2 spectral band using a neural network approach

Author

Chimot, Julien, Veefkind, J. Pepijn, Vlemmix, Tim, Haan, Johan F., Amiridis, Vassilis, Proestakis, Emmanouil, Marinou, Eleni, and Levelt, Pieternel F.

Subjects

lcsh:TA715-787, lcsh:Earthwork. Foundations, lcsh:TA170-171, lcsh:Environmental engineering

Abstract

This paper presents an exploratory study on the aerosol layer height (ALH) retrieval from the OMI 477 nm O2 − O2 spectral band. We have developed algorithms based on the multilayer perceptron (MLP) neural network (NN) approach and applied them to 3-year (2005–2007) OMI cloud-free scenes over north-east Asia, collocated with MODIS Aqua aerosol product. In addition to the importance of aerosol altitude for climate and air quality objectives, our long-term motivation is to evaluate the possibility of retrieving ALH for potential future improvements of trace gas retrievals (e.g. NO2, HCHO, SO2) from UV–visible air quality satellite measurements over scenes including high aerosol concentrations. This study presents a first step of this long-term objective and evaluates, from a statistic point of view, an ensemble of OMI ALH retrievals over a long time period of 3 years covering a large industrialized continental region. This ALH retrieval relies on the analysis of the O2 − O2 slant column density (SCD) and requires an accurate knowledge of the aerosol optical thickness, τ. Using MODIS Aqua τ(550 nm) as a prior information, absolute seasonal differences between the LIdar climatology of vertical Aerosol Structure for space-based lidar simulation (LIVAS) and average OMI ALH, over scenes with MODIS τ(550 nm) ≥ 1. 0, are in the range of 260–800 m (assuming single scattering albedo ω0 = 0. 95) and 180–310 m (assuming ω0 = 0. 9). OMI ALH retrievals depend on the assumed aerosol single scattering albedo (sensitivity up to 660 m) and the chosen surface albedo (variation less than 200 m between OMLER and MODIS black-sky albedo). Scenes with τ ≤ 0. 5 are expected to show too large biases due to the little impact of particles on the O2 − O2 SCD changes. In addition, NN algorithms also enable aerosol optical thickness retrieval by exploring the OMI reflectance in the continuum. Comparisons with collocated MODIS Aqua show agreements between −0. 02 ± 0. 45 and −0. 18 ± 0. 24, depending on the season. Improvements may be obtained from a better knowledge of the surface albedo and higher accuracy of the aerosol model. Following the previous work over ocean of Park et al.(2016), our study shows the first encouraging aerosol layer height retrieval results over land from satellite observations of the 477 nm O2 − O2 absorption spectral band.

Published

2017

11. Retrieval of tropospheric NO2 columns over Berlin from high-resolution airborne observations with the spectrolite breadboard instrument

Author

Vlemmix, Tim, Ge, Xinrui (Jerry), Goeij, Bryan T. G., Wal, Len F., Otter, Gerard C. J., Stammes, Piet, Wang, Ping, Merlaud, Alexis, Schüttemeyer, Dirk, Meier, Andreas C., Veefkind, J. Pepijn, and Levelt, Pieternel F.

Abstract

This paper presents the retrieval method that was developed to derive tropospheric NO2 columns from UV/VIS spectral measurements obtained with the Spectrolite Breadboard Instrument during the AROMAPEX campaign in Berlin (April 2016). A typical DOAS retrieval approach is followed. For the calculation of air mass factors this study specifically focuses on the impact of the surface reflectance, which varies considerably from pixel to pixel over this urban region. Ground-based aerosol optical thickness measurements are used as prior information. It is shown that retrieved surface reflectance shows good agreement with those derived from Landsat 8 measurements performed on the same day. Furthermore we demonstrate that tropospheric NO2 columns retrieved for pairs of adjacent pixels are self-consistent in the sense that they do not show a substantial systematic dependence on surface reflectance, in contrast to differential slant column densities. Also some cases are identified to illustrate this on a pixel-by-pixel level. An error budget is provided to quantify the impact of various assumptions on the accuracy of the retrieval of surface reflectance and tropospheric NO2 columns. Both in the morning and afternoon flight a NO2 plume is observed stretching out over Berlin from West to East. Peak values between 15 × 1015 and 20 × 1015 molec/cm2 are detected, whereas – at much lower spatial resolution – OMI detects peak values between 9 × 1015 (first overpass) and 4 × 1015 molec/cm2 (second overpass).

Published

2018

12. Aerosol layer height from OMI and neural network – Evaluation and possibility of a 13-year time series?

Author

Chimot, Julien, Veefkind, Pepijn, Ouwerkerk, Gijs Van, Vlemmix, Tim, and Levelt, Pieternel

Published

2018

13. Intercomparison of MAX-DOAS vertical profile retrieval algorithms: studies using synthetic data

Author

Frieß, Udo, primary, Beirle, Steffen, additional, Alvarado Bonilla, Leonardo, additional, Bösch, Tim, additional, Friedrich, Martina M., additional, Hendrick, François, additional, Piters, Ankie, additional, Richter, Andreas, additional, van Roozendael, Michel, additional, Rozanov, Vladimir V., additional, Spinei, Elena, additional, Tirpitz, Jan-Lukas, additional, Vlemmix, Tim, additional, Wagner, Thomas, additional, and Wang, Yang, additional

Published

2019

14. Intercomparison of four airborne imaging DOAS systems for tropospheric NO<sub>2</sub> mapping – the AROMAPEX campaign

Author

Tack, Frederik, primary, Merlaud, Alexis, additional, Meier, Andreas C., additional, Vlemmix, Tim, additional, Ruhtz, Thomas, additional, Iordache, Marian-Daniel, additional, Ge, Xinrui, additional, van der Wal, Len, additional, Schuettemeyer, Dirk, additional, Ardelean, Magdalena, additional, Calcan, Andreea, additional, Constantin, Daniel, additional, Schönhardt, Anja, additional, Meuleman, Koen, additional, Richter, Andreas, additional, and Van Roozendael, Michel, additional

Published

2019

15. Intercomparison of MAX-DOAS Vertical Profile Retrieval Algorithms: Studies using Synthetic Data

Author

Frieß, Udo, primary, Beirle, Steffen, additional, Alvarado Bonilla, Leonardo, additional, Bösch, Tim, additional, Friedrich, Martina M., additional, Hendrick, Francois, additional, Piters, Ankie, additional, Richter, Andreas, additional, van Roozendael, Michel, additional, Rozanov, Vladimir V., additional, Spinei, Elena, additional, Tirpitz, Jan-Lukas, additional, Vlemmix, Tim, additional, Wagner, Thomas, additional, and Wang, Yang, additional

Published

2018

16. Supplementary material to "Intercomparison of MAX-DOAS Vertical Profile Retrieval Algorithms: Studies using Synthetic Data"

Author

Frieß, Udo, primary, Beirle, Steffen, additional, Alvarado Bonilla, Leonardo, additional, Bösch, Tim, additional, Friedrich, Martina M., additional, Hendrick, Francois, additional, Piters, Ankie, additional, Richter, Andreas, additional, van Roozendael, Michel, additional, Rozanov, Vladimir V., additional, Spinei, Elena, additional, Tirpitz, Jan-Lukas, additional, Vlemmix, Tim, additional, Wagner, Thomas, additional, and Wang, Yang, additional

Published

2018

17. Aerosol layer height retrieval from OMI+MODIS - A neural network approach

Author

Chimot, Julien, Veefkind, Pepijn, Vlemmix, Tim, Haan, Johan De, and Levelt, Pieternel

Published

2017

18. Aerosol layer height from OMI and neural network Possibility of a 13-year time series?

Author

Chimot, Julien, Veefkind, Pepijn, Ouwerkerk, Gijs Van, Vlemmix, Tim, and Levelt, Pieternel

Published

2017

19. Spatial distribution analysis of the OMI aerosol layer height: a pixel-by-pixel comparison to CALIOP observations

Author

Chimot, Julien, primary, Veefkind, J. Pepijn, additional, Vlemmix, Tim, additional, and Levelt, Pieternel F., additional

Published

2018

20. Intercomparison of four airborne imaging DOAS systems for tropospheric NO2 mapping – The AROMAPEX campaign

Author

Tack, Frederik, primary, Merlaud, Alexis, additional, Meier, Andreas C., additional, Vlemmix, Tim, additional, Ruhtz, Thomas, additional, Iordache, Marian-Daniel, additional, Ge, Xinrui, additional, van der Wal, Len, additional, Schuettemeyer, Dirk, additional, Ardelean, Magdalena, additional, Calcan, Andreea, additional, Schönhardt, Anja, additional, Meuleman, Koen, additional, Richter, Andreas, additional, and Van Roozendael, Michel, additional

Published

2018

21. Satellite nadir NO2 validation based on zenith-sky, direct-sun and MAXDOAS network observations

Author

Pinardi, Gaia, Van Roozendael, Michel, Lambert, Jean-Christopher, Granville, José, Hendrick, François, Gielen, Clio, Cede, Alexander, Kanaya, Ygo, Irie, Hitoshi, Wittrock, Folkard, Richter, Andreas, Peters, Enno, Wagner, Thomas, Gu, Myojeong, Remmers, Julia, Lampel, Johannes, Friess, Udo, Vlemmix, Tim, Piters, Ankie, Hao, Nan, Tiefengraber, Martin, Herman, Jay, Abuhassan, Nader, Holla, Robert, Bais, Alkis, Balis, Dimitris, Drosoglou, Theano, Kouremeti, Natalia, Hovila, Jari, Chong, J., Postylyakov, Oleg, Ma, Jianzhong, Goutail, Florence, Pommereau, Jean-Pierre, Pazmino, Andrea, Navarro, Monica, Puentedura, Olga, Yu, Huan, Belgian Institute for Space Aeronomy / Institut d'Aéronomie Spatiale de Belgique (BIRA-IASB), NASA Goddard Space Flight Center (GSFC), Research Institute for Global Change (RIGC), Japan Agency for Marine-Earth Science and Technology (JAMSTEC), Center for Environmental Remote Sensing [Chiba] (CEReS), Chiba University, Institute of Environmental Physics [Bremen] (IUP), University of Bremen, Max Planck Institute for Chemistry (MPIC), Max-Planck-Gesellschaft, Institut für Umweltphysik [Heidelberg], Universität Heidelberg [Heidelberg], Department of Geoscience and Remote Sensing [Delft], Delft University of Technology (TU Delft), Royal Netherlands Meteorological Institute (KNMI), DLR Institut für Methodik der Fernerkundung / DLR Remote Sensing Technology Institute (IMF), Deutsches Zentrum für Luft- und Raumfahrt [Oberpfaffenhofen-Wessling] (DLR), Institute of Meteorology and Geophysics [Innsbruck], University of Innsbruck, Joint Center for Earth Systems Technology [Baltimore] (JCET), NASA Goddard Space Flight Center (GSFC)-University of Maryland [Baltimore County] (UMBC), University of Maryland System-University of Maryland System, Meteorologisches Observatorium Hohenpeißenberg (MOHp), Deutscher Wetterdienst [Offenbach] (DWD), Laboratory of Atmospheric Physics [Thessaloniki], Aristotle University of Thessaloniki, Physikalisch-Meteorologisches Observatorium Davos/World Radiation Center (PMOD/WRC), Finnish Meteorological Institute (FMI), Gwangju Institute of Science and Technology (GIST), A.M.Obukhov Institute of Atmospheric Physics (IAP), Russian Academy of Sciences [Moscow] (RAS), Chinese Academy of Meteorological Sciences (CAMS), STRATO - LATMOS, Laboratoire Atmosphères, Milieux, Observations Spatiales (LATMOS), Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), Instituto Nacional de Técnica Aeroespacial (INTA), Cardon, Catherine, Universität Heidelberg [Heidelberg] = Heidelberg University, and Leopold Franzens Universität Innsbruck - University of Innsbruck

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; Since more than fifteen years, total and tropospheric NO2 columns have been retrieved from nadir space-borne sensors such as SCIAMACHY on ENVISAT, OMI on AURA and GOME-2 on MetOp platforms. The NO2 data products are generally retrieved in three main steps: (1) a DOAS spectral analysis yielding the total column amount of NO2 along the slant optical path, (2) an estimation of the stratospheric NO2 column, to be subtracted from the total column to derive the tropospheric contribution, and (3) a conversion of the total and tropospheric slant columns into vertical columns based on airmass factor calculations which require a-priori knowledge of the NO2 vertical distribution and surface albedo, as well as information on cloud cover and height.In this study we combine correlative measurements available from several ground-based remote sensing networks to address the validation of (1) the GOME-2 GDP 4.8 NO2 products generated within the EUMETSAT O3M-SAF project, and (2) the SCIAMACHY, OMI and GOME-2 TEMIS product. Zenith-sky DOAS/SAOZ measurements from the NDACC network are used to assess the stratospheric NO2 columns retrieved from the satellite, while the consistency of the total and tropospheric NO2 columns in urban, sub-urban and back-ground conditions is investigated using direct-sun Pandora and multi-axis MAXDOAS data sets from about 40 stations. Where available, vertical profile information from MAXDOAS measurements is used to assess the reliability of the different satellite a-priori profile shapes.Results are discussed in terms of observed biases between satellite and ground-based data sets, their dependence on location, season and cloud conditions. For stratospheric columns, the uncertainty related to the correction applied for ensuring the photochemical matching between satellite and ground-based observations is also evaluated. The satellite pixels resolution effect is statistically explored in relation to the typical extent of the emission sources at urban site locations, using data from SCIAMACHY 60x30 km², GOME-2 40x80 km² and OMI 13x24 km².

Published

2016

22. Retrieving aerosol height from space: A neural network approach applied to OMI O2-O2 measurements

Author

Chimot, Julien, Veefkind, Pepijn, Vlemmix, Tim, Haan, Johan De, and Levelt, Pieternel

Published

2016

23. Spatial distribution analysis of the OMI aerosol layer height: a pixel-by-pixel comparison to CALIOP observations

Author

Chimot, Julien, primary, Veefkind, J. Pepijn, additional, Vlemmix, Tim, additional, and Levelt, Pieternel F., additional

Published

2017

24. co-author list incomplete

Author

Vlemmix, Tim, primary

Published

2017

25. Retrieval of tropospheric NO<sub>2</sub> columns over Berlin from high-resolution airborne observations with the spectrolite breadboard instrument

Author

Vlemmix, Tim, primary, Ge, Xinrui (Jerry), additional, de Goeij, Bryan T. G., additional, van der Wal, Len F., additional, Otter, Gerard C. J., additional, Stammes, Piet, additional, Wang, Ping, additional, Merlaud, Alexis, additional, Schüttemeyer, Dirk, additional, Meier, Andreas C., additional, Veefkind, J. Pepijn, additional, and Levelt, Pieternel F., additional

Published

2017

26. Comparison of tropospheric NO2 columns from MAX-DOAS retrievals and regional air quality model simulations

Author

Blechschmidt, Anne-Marlene, primary, Arteta, Joaquim, additional, Coman, Adriana, additional, Curier, Lyana, additional, Eskes, Henk, additional, Foret, Gilles, additional, Gielen, Clio, additional, Hendrick, Francois, additional, Marécal, Virginie, additional, Meleux, Frédérik, additional, Parmentier, Jonathan, additional, Peters, Enno, additional, Pinardi, Gaia, additional, Piters, Ankie J. M., additional, Plu, Matthieu, additional, Richter, Andreas, additional, Sofiev, Mikhail, additional, Valdebenito, Álvaro M., additional, Van Roozendael, Michel, additional, Vira, Julius, additional, Vlemmix, Tim, additional, and Burrows, John P., additional

Published

2017

27. Intercomparison of MAX-DOAS Vertical Profile Retrieval Algorithms: Studies using Synthetic Data.

Author

Frieß, Udo, Beirle, Steffen, Bonilla, Leonardo Alvarado, Bösch, Tim, Friedrich, Martina M., Hendrick, Francois, Piters, Ankie, Richter, Andreas, van Roozendael, Michel, Rozanov, Vladimir V., Spinei, Elena, Tirpitz, Jan-Lukas, Vlemmix, Tim, Wagner, Thomas, and Yang Wang

Subjects

TRACE gases, ATMOSPHERIC aerosols

Abstract

Multi-Axis Differential Optical Absorption Spectroscopy (MAX-DOAS) is a widely used measurement technique for the detection of a variety of atmospheric trace gases. Using inverse modelling, the observation of trace gas column densities along different lines of sight enables the retrieval of aerosol and trace gas vertical profiles in the atmospheric boundary layer using appropriate retrieval algorithms. In this study, the ability of eight profile retrieval algorithms to reconstruct vertical profiles is assessed on the basis of synthetic measurements. Five of the algorithms are based on the optimal estimation method, two on parametrised approaches, and one using an analytical approach without involving any radiative transfer modelling. The synthetic measurements consist of the median of simulated slant column densities of O4 at 360nm and 477nm, as well as of HCHO at 343nm and NO2 at 477nm, from seven datasets simulated by five different radiative transfer models. Simulations are performed for a combination of 10 trace gas and 11 aerosol profiles, as well as 11 elevation angles, 3 solar 10 zenith and 3 relative azimuth angles. Overall, the results from the different algorithms show moderate to good performance for the retrieval of vertical profiles, surface concentrations and total columns. Except for some outliers, the root mean squares difference between true and retrieved state ranges between (0:05-0:1) km1 for aerosol extinction, and (2:5-5:0) × 1010molec/cm3 for HCHO and NO2 concentrations. [ABSTRACT FROM AUTHOR]

Published

2018

28. An exploratory study on the aerosol height retrieval from OMI measurements of the 477 nm O2–O2 spectral band, using a Neural Network approach

Author

Chimot, Julien, primary, Veefkind, Joris Pepijn, additional, Vlemmix, Tim, additional, de Haan, Johan, additional, Amiridis, Vassilis, additional, Proestakis, Emmanouil, additional, Marinou, Eleni, additional, and Levelt, Pieternel Felicitas, additional

Published

2016

29. Intercomparison of four airborne imaging DOAS systems for tropospheric NO2 mapping -- The AROMAPEX campaign.

Author

Tack, Frederik, Merlaud, Alexis, Meier, Andreas C., Vlemmix, Tim, Ruhtz, Thomas, Iordache, Marian-Daniel, Xinrui Ge, van der Wal, Len, Schuettemeyer, Dirk, Ardelean, Magdalena, Calcan, Andreea, Schönhardt, Anja, Meuleman, Koen, Richter, Andreas, and Van Roozendael, Michel

Subjects

NITROGEN dioxide, TROPOSPHERIC circulation, AIR masses

Abstract

We present an intercomparison study of four airborne imaging DOAS instruments, dedicated to the retrieval and high resolution mapping of tropospheric nitrogen dioxide (NO2) vertical column densities (VCDs). The AROMAPEX campaign took place in Berlin, Germany in April, 2016 with the primary objective to test and intercompare the performance of experimental airborne imagers. The imaging DOAS instruments were operated simultaneously from two manned aircraft, performing synchronised flights: APEX (VITO/BIRA-IASB) was operated from DLR's DO-228 D-CFFU aircraft at 6.2 km altitude, while AirMAP (IUP-Bremen), SWING (BIRA-IASB) and SBI (TNO/TU Delft/KNMI) were operated from the FUB Cessna 207T D-EAFU at 3.1 km. Two synchronised flights took place on 21 April 2016. NO2 slant columns were retrieved by applying differential optical absorption spectroscopy (DOAS) in the visible wavelength region and converted to VCDs by the computation of appropriate air mass factors (AMFs). Finally, the NO2 VCDs were georeferenced and mapped at high spatial resolution. For the sake of harmonising the different data sets, efforts were made to agree on a common set of parameter settings, AMF LUT and gridding algorithm. The NO2 horizontal distribution, observed by the different DOAS imagers, shows very similar spatial patterns. The NO2 field is dominated by two large plumes related to industrial compounds, crossing the city from west to east. The major highways A100 and A113 are also identified as line sources of NO2. Retrieved NO2 VCDs range between 1 x 1015 molec cm-2 upwind of the city and 20 x 1015 molec cm-2 in the dominant plume, with a mean of 7.3 ± 1.8 x 1015 molec cm-2 for the morning flight and between 1 and 23 x 1015 molec cm-2 with a mean of 6.0 ± 1.4 x 1015 molec cm-2 for the afternoon flight. The mean NO2 VCD retrieval errors are in the range of 22 to 36 % for all sensors. The four data sets are in good agreement with Pearson correlation coefficients better than 0.9, while the linear regression analyses show slopes close to unity and generally small intercepts. [ABSTRACT FROM AUTHOR]

Published

2018

30. Spatial distribution analysis of the OMI aerosol layer height: a pixel-by-pixel comparison to CALIOP observations.

Author

Chimot, Julien, Veefkind, J. Pepijn, Vlemmix, Tim, and Levelt, Pieternel F.

Subjects

SPATIAL distribution (Quantum optics), ATMOSPHERIC aerosols, MODIS (Spectroradiometer)

Abstract

A global picture of atmospheric aerosol vertical distribution with a high temporal resolution is of key importance not only for climate, cloud formation and air quality research studies, but also for correcting aerosol radiation effect in absorbing trace gas retrievals from passive satellite sensors. Aerosol layer height (ALH) was retrieved from the OMI 477 nm O2-O2 band and its spatial pattern evaluated over selected cloud-free scenes. Such retrievals benefit from a synergy with MODIS data to provide complementary information on aerosols and cloudy pixels. We used a neural network approach previously trained and developed. Comparison with CALIOP aerosol level 2 products over urban and industrial pollution in east China shows consistent spatial patterns with an uncertainty in the range of 462-648 m. In addition, we show the possibility to determine the height of thick aerosol layers released by intensive biomass burning events in South-America and Russia, and of a Saharan dust outbreak over sea from OMI visible measurements. Complementary detailed analyses show that the assumed aerosol properties in the modeling are the key factors affecting the accuracy of the results, together with potential cloud residuals in the observation pixels. Furthermore, we demonstrate that the physical meaning of the retrieved ALH scalar corresponds to the weighted average of the vertical aerosol extinction profile. These encouraging findings strongly suggest the potential of the OMI ALH product, and in more general the use of the 477 nm O2-O2 band from present and future similar satellite sensors, for climate studies as well as for future aerosol correction in air quality trace gas retrievals. [ABSTRACT FROM AUTHOR]

Published

2017

31. Retrieval of tropospheric NO2 columns over Berlin from high-resolution airborne observations with the spectrolite breadboard instrument.

Author

Vlemmix, Tim, Ge, Xinrui (Jerry), de Goeij, Bryan T. G., van der Wal, Len F., Otter, Gerard C. J., Stammes, Piet, Ping Wang, Merlaud, Alexis, Schüttemeyer, Dirk, Meier, Andreas C., Veefkind, J. Pepijn, and Levelt, Pieternel F.

Subjects

*ATMOSPHERIC nitrogen dioxide, *LANDSAT satellites, *HIGH resolution imaging

Abstract

This paper presents the retrieval method that was developed to derive tropospheric NO2 columns from UV/VIS spectral measurements obtained with the Spectrolite Breadboard Instrument during the AROMAPEX campaign in Berlin (April 2016). A typical DOAS retrieval approach is followed. For the calculation of air mass factors this study specifically focuses on the impact of the surface reflectance, which varies considerably from pixel to pixel over this urban region. Ground-based aerosol optical thickness measurements are used as prior information. It is shown that retrieved surface reflectance shows good agreement with those derived from Landsat 8 measurements performed on the same day. Furthermore we demonstrate that tropospheric NO2 columns retrieved for pairs of adjacent pixels are self-consistent in the sense that they do not show a substantial systematic dependence on surface reflectance, in contrast to differential slant column densities. Also some cases are identified to illustrate this on a pixel-by-pixel level. An error budget is provided to quantify the impact of various assumptions on the accuracy of the retrieval of surface reflectance and tropospheric NO2 columns. Both in the morning and afternoon flight a NO2 plume is observed stretching out over Berlin from West to East. Peak values between 15 × 1015 and 20 × 1015 molec/cm² are detected, whereas - at much lower spatial resolution - OMI detects peak values between 9 × 1015 (first overpass) and 4 × 1015 molec/cm² (second overpass). [ABSTRACT FROM AUTHOR]

Published

2017

32. An exploratory study on the aerosol height retrieval from OMI measurements of the 477 nm O2-O2 spectral band, using a Neural Network approach.

Author

Chimot, Julien, Veefkind, Joris Pepijn, Vlemmix, Tim, de Haan, Johan, Amiridis, Vassilis, Proestakis, Emmanouil, Marinou, Eleni, and Levelt, Pieternel Felicitas

Subjects

ATMOSPHERIC aerosols spectra, ATMOSPHERIC aerosol measurement, MODIS (Spectroradiometer)

Abstract

This paper presents an exploratory study on the retrieval of aerosol layer height (ALH) from the OMI 477 nm O2-O2 spectral band. We have developed algorithms based on the Multilayer Perceptron (MLP) Neural Network (NN) approach and applied them on 3-year (2005-2007) OMI cloud-free scenes over North-East Asia, collocated with MODIS-Aqua aerosol product. In addition to the importance of aerosol altitude for climate and air quality objectives, the main motivation of this study is to evaluate the possibility of retrieving ALH for potential future improvements of trace gas retrievals (e.g. NO2, HCHO, SO2, etc..) from UV-Vis air quality satellite measurements over scenes including high aerosol concentrations. ALH retrieval relies on the analysis of the O2-O2 slant column density (SCD) and requires an accurate knowledge of the aerosol optical thickness τ. Using the MODIS-Aqua aerosol optical thickness at 550 nm as a prior information, comparison with the LIdar climatology of vertical Aerosol Structure for space-based lidar simulation (LIVAS) shows that ALH average biases over scenes with MODIS τ ≥ are in the range of 260-800 m. These results depend on the assumed aerosol single scattering albedo (sensitivity up to 600 m) and the chosen surface albedo (variation less than 200 m). Scenes with τ ≤ 0.5 are expected to show too large biases due to the little impacts of particles on the O2-O2 SCD changes. In addition, NN algorithms also enable aerosol optical thickness retrieval by exploring the OMI reflectance in the continuum. Comparisons with collocated MODIS-Aqua show agreements between -0.02 ± 0.45 and -0.18 ± 0.24 depending on the season. Improvements may be obtained from a better knowledge of the surface albedo, and higher accuracy of the aerosol model. This study shows the first encouraging aerosol layer height retrieval results over land from satellite observations of the 477 nm O2-O2 spectral band. [ABSTRACT FROM AUTHOR]

Published

2016

33. First deployment of the Spectrolite Breadboard Instrument for monitoring of tropospheric NO2 columns over Berlin.

Author

Vlemmix, Tim, Ge, Xinrui (Jerry), de Goeij, Bryan, van der Wal, Len, Otter, Gerard, Stammes, Piet, Ping Wang, Merlaud, Alexis, Schuettemeyer, Dirk, Ruhtz, Thomas, Meier, Andreas, Veefkind, Pepijn, and Levelt, Pieternel

Subjects

BERLIN (Germany)

Published

2018

34. The Ozone Monitoring Instrument: towards a 14 year data record and applications in the air quality and climate domain.

Author

Levelt, Pietenel, Joiner, Joanna, Tamminen, Johanna, Veefkind, Pepijn, Bhartia, Pawan, Court, Andy, and Vlemmix, Tim

Published

2018

35. Comparison of algorithms for the retrieval of aerosol and trace gas vertical profiles using synthetic MAX-DOAS data.

Author

Frieß, Udo, Beirle, Steffen, Bonilla, Leonardo Alvarado, Bösch, Tim, Fayt, Caroline, Friedrich, Martina M., Hendrick, François, Piters, Ankie, Richter, Andreas, van Roozendael, Michel, Spinei, Elena, Tirpitz, Jan-Lukas, Vlemmix, Tim, Wagner, Thomas, and Yang Wang

Published

2018