Your search keyword '"Stammes, Piet"' showing total 334 results

1. Clouds dissipate quickly during solar eclipses as the land surface cools

Author

Trees, Victor J. H., de Roode, Stephan R., Wiltink, Job I., Meirink, Jan Fokke, Wang, Ping, Stammes, Piet, and Siebesma, A. Pier

Subjects

Physics - Atmospheric and Oceanic Physics, Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Solar and Stellar Astrophysics, Physics - Geophysics

Abstract

Clouds affected by solar eclipses could influence the reflection of sunlight back into space and might change local precipitation patterns. Satellite cloud retrievals have so far not taken into account the lunar shadow, hindering a reliable spaceborne assessment of the eclipse-induced cloud evolution. Here we use satellite cloud measurements during three solar eclipses between 2005 and 2016 that have been corrected for the partial lunar shadow together with large-eddy simulations to analyze the eclipse-induced cloud evolution. Our corrected data reveal that, over cooling land surfaces, shallow cumulus clouds start to disappear at very small solar obscurations. Our simulations explain that the cloud response was delayed and was initiated at even smaller solar obscurations. We demonstrate that neglecting the disappearance of clouds during a solar eclipse could lead to a considerable overestimation of the eclipse-related reduction of net incoming solar radiation. These findings should spur cloud model simulations of the direct consequences of sunlight-intercepting geoengineering proposals, for which our results serve as a unique benchmark.

Published

2024

2. Extended aerosol and surface characterization from S5P/TROPOMI with GRASP algorithm. Part II: Global validation and Intercomparison

Author

Chen, Cheng, Litvinov, Pavel, Dubovik, Oleg, Bindreiter, Lukas, Matar, Christian, Fuertes, David, Lopatin, Anton, Lapyonok, Tatyana, Lanzinger, Verena, Hangler, Andreas, Aspetsberger, Michael, de Graaf, Martin, Tilstra, Lieuwe Gijsbert, Stammes, Piet, Dandocsi, Alexandru, Gasbarra, Daniele, Fluck, Elody, Zehner, Claus, and Retscher, Christian

Published

2024

3. Extended aerosol and surface characterization from S5P/TROPOMI with GRASP algorithm. Part I: Conditions, approaches, performance and new possibilities

Author

Litvinov, Pavel, Chen, Cheng, Dubovik, Oleg, Bindreiter, Lukas, Matar, Christian, Fuertes, David, Lopatin, Anton, Lapyonok, Tatyana, Lanzinger, Verena, Hangler, Andreas, Aspetsberger, Michael, de Graaf, Martin, Tilstra, Lieuwe Gijsbert, Stammes, Piet, Dandocsi, Alexandru, Gasbarra, Daniele, Fluck, Elody, Zehner, Claus, and Retscher, Christian

Published

2024

4. Restoring the top-of-atmosphere reflectance during solar eclipses: a proof of concept with the UV Absorbing Aerosol Index measured by TROPOMI

Author

Trees, Victor J. H., Wang, Ping, and Stammes, Piet

Subjects

Physics - Atmospheric and Oceanic Physics, Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Solar and Stellar Astrophysics

Abstract

During a solar eclipse the solar irradiance reaching the top-of-atmosphere (TOA) is reduced in the Moon shadow. The solar irradiance is commonly measured by Earth observation satellites before the start of the solar eclipse and is not corrected for this reduction, which results in a decrease of the computed TOA reflectances. Consequently, air quality products that are derived from TOA reflectance spectra, such as the ultraviolet (UV) Absorbing Aerosol Index (AAI), are distorted or undefined in the shadow of the Moon. The availability of air quality satellite data in the penumbral and antumbral shadow during solar eclipses, however, is of particular interest to users studying the atmospheric response to solar eclipses. Given the time and location of a point on the Earth's surface, we explain how to compute the obscuration during a solar eclipse taking into account wavelength-dependent solar limb darkening. With the calculated obscuration fractions, we restore the TOA reflectances and the AAI in the penumbral shadow during the annular solar eclipses on 26 December 2019 and 21 June 2020 measured by the TROPOMI/S5P instrument. In the corrected products, the signature of the Moon shadow disappeared, but only if wavelength-dependent solar limb darkening is taken into account. We conclude that the correction method of this paper can be used to detect real AAI rising phenomena during a solar eclipse and has the potential to restore any other product that is derived from TOA reflectance spectra. This would resolve the solar eclipse anomalies in satellite air quality measurements and would allow for studying the effect of the eclipse obscuration on the composition of the Earth's atmosphere from space., Comment: Accepted for publication in Atmospheric Chemistry and Physics

Published

2021

5. Clouds dissipate quickly during solar eclipses as the land surface cools

Author

Trees, V.J.H. (author), de Roode, S.R. (author), Wiltink, Job I. (author), Meirink, Jan Fokke (author), Wang, P. (author), Stammes, Piet (author), Siebesma, A.P. (author), Trees, V.J.H. (author), de Roode, S.R. (author), Wiltink, Job I. (author), Meirink, Jan Fokke (author), Wang, P. (author), Stammes, Piet (author), and Siebesma, A.P. (author)

Abstract

Clouds affected by solar eclipses could influence the reflection of sunlight back into space and might change local precipitation patterns. Satellite cloud retrievals have so far not taken into account the lunar shadow, hindering a reliable spaceborne assessment of the eclipse-induced cloud evolution. Here we use satellite cloud measurements during three solar eclipses between 2005 and 2016 that have been corrected for the partial lunar shadow together with large-eddy simulations to analyze the eclipse-induced cloud evolution. Our corrected data reveal that, over cooling land surfaces, shallow cumulus clouds start to disappear at very small solar obscurations (~15%). Our simulations explain that the cloud response was delayed and was initiated at even smaller solar obscurations. We demonstrate that neglecting the disappearance of clouds during a solar eclipse could lead to a considerable overestimation of the eclipse-related reduction of net incoming solar radiation. These findings should spur cloud model simulations of the direct consequences of sunlight-intercepting geoengineering proposals, for which our results serve as a unique benchmark., Atmospheric Remote Sensing

Published

2024

6. Clouds dissipate quickly during solar eclipses as the land surface cools

Author

Trees, Victor J.H., de Roode, Stephan R., Wiltink, Job I., Meirink, Jan Fokke, Wang, Ping, Stammes, Piet, Siebesma, A.P., Trees, Victor J.H., de Roode, Stephan R., Wiltink, Job I., Meirink, Jan Fokke, Wang, Ping, Stammes, Piet, and Siebesma, A.P.

Abstract

Clouds affected by solar eclipses could influence the reflection of sunlight back into space and might change local precipitation patterns. Satellite cloud retrievals have so far not taken into account the lunar shadow, hindering a reliable spaceborne assessment of the eclipse-induced cloud evolution. Here we use satellite cloud measurements during three solar eclipses between 2005 and 2016 that have been corrected for the partial lunar shadow together with large-eddy simulations to analyze the eclipse-induced cloud evolution. Our corrected data reveal that, over cooling land surfaces, shallow cumulus clouds start to disappear at very small solar obscurations (~15%). Our simulations explain that the cloud response was delayed and was initiated at even smaller solar obscurations. We demonstrate that neglecting the disappearance of clouds during a solar eclipse could lead to a considerable overestimation of the eclipse-related reduction of net incoming solar radiation. These findings should spur cloud model simulations of the direct consequences of sunlight-intercepting geoengineering proposals, for which our results serve as a unique benchmark.

Published

2024

7. Retrieval of Aerosol and Surface Properties at High Spatial Resolution: Hybrid Approach and Demonstration Using Sentinel‐5p/TROPOMI and PRISMA.

Author

Chen, Cheng, Litvinov, Pavel, Dubovik, Oleg, Fuertes, David, Matar, Christian, Miglietta, Franco, Pepe, Monica, Genesio, Lorenzo, Busetto, Lorenzo, Bindreiter, Lukas, Lanzinger, Verena, de Graaf, Martin, Tilstra, Gijsbert, Stammes, Piet, and Retscher, Christian

Subjects

SPATIAL resolution, AIR quality, SURFACE properties, SURFACE analysis, AEROSOLS

Abstract

Satellite remote sensing of aerosol is largely conducted at moderate or coarse spatial resolution around 1–10 km. Nevertheless, at urban areas with high human activity, aerosol can originate from complex emission sources and may also vary strongly in space. Therefore, aerosol characterization at fine spatial resolution is essential for air quality study and assessment of anthropogenic pollution as well as climate effects. However, space‐borne instruments with high spatial resolution are usually limited in swath width or spectral coverage which result in lowering information content required for aerosol and surface retrieval. Based on the Generalized Retrieval of Atmosphere and Surface Properties (GRASP) algorithm, we propose a hybrid approach by combining fine and coarse spatial resolution measurements to retrieve aerosol and surface properties simulataneously at fine spatial resolution. The instruments with coarse spatial resolution and high revisting time can provide advanced aerosol characterization. At the same time, the instruments with fine spatial resolution are sensitive to spatial variability of aerosol nearby sources. In this study, the GRASP/Hybrid approach is demonstrated and tested based on the European Space Agency Sentinel‐5p/TROPOMI together with the Italian Space Agency PRISMA satellite data. Specifically, the detailed aerosol microphysical properties from Sentinel‐5p/TROPOMI 10 km retrievals are used as a priori information for PRISMA to derive aerosol loading and surface properties at 100 meter (m) spatial resolution. The PRISMA 100 m aerosol and surface retrieval based on the developed GRASP/Hybrid approach are evaluated using available ground‐based and satellite measurements, including AERONET, VIIRS/DB aerosol and PRISMA Level 2 surface reflectance products. Plain Language Summary: Both aerosol and surface characterization at high spatial resolution are always highly demanded especially over densely populated urban areas. However, the high spatial resolution space‐borne instruments typically have small swaths that, in general, reduce the possibility of aerosol and surface decoupling. In this paper, we develop a hybrid approach based on GRASP algorithm (GRASP/Hybrid) to retrieve aerosol and surface properties at fine spatial granularity by combining fine and coarse spatial resolution satellite data. The GRASP/Hybrid approach is demonstrated using European Space Agency (ESA) Sentinel‐5p/TROPOMI and Italian Space Agency (ASI) PRISMA (Hyperspectral Precursor of the Application Mission) measurements. Specifically, the detailed aerosol microphysical properties from Sentinel‐5p/TROPOMI 10 km retrievals are used as a priori information to derive aerosol loading and surface properties exploiting PRISMA at 100 m spatial resolution. Overall, the results obtained in this study demonstrate the big potential of the approach based on the combination of instruments for a number of climate and environment monitoring studies. Key Points: Generalized Retrieval of Atmosphere and Surface Properties (GRASP)/Hybrid approach is developed and demonstrated using Sentinel‐5p/TROPOMI and PRISMA measurementsPRISMA 100 m aerosol and surface properties are retrieved based on GRASP/Hybrid approach and evaluated using reference data setsWe demonstrate the big potential of hybrid approach based on the combination of instruments for climate and environment studies [ABSTRACT FROM AUTHOR]

Published

2024

8. Calm ocean, stormy sea: Atmospheric and oceanographic observations of the Atlantic during the ARC ship campaign.

Author

Köhler, Laura, Windmiller, Julia, Baranowski, Dariusz, Brennek, Michał, Ciuryło, Michał, Hayo, Lennéa, Kepski, Daniel, Kinne, Stefan, Latos, Beata, Lobo, Bertrand, Marke, Tobias, Nischik, Timo, Paul, Daria, Stammes, Piet, Szkop, Artur, and Tuinder, Olaf

Subjects

INTERTROPICAL convergence zone, OCEANOGRAPHIC observations, CEILOMETER, RADIOSONDES, AEROSOLS

Abstract

During the Atlantic References and Convection (ARC) ship campaign with the reference MSM114/2, which took place in early 2023, the German research vessel Maria S. Merian travelled from Mindelo, Cape Verde, to Punta Arenas, Chile. One of the main objectives of ARC was to obtain vertically resolved cross sections of the Intertropical Convergence Zone (ITCZ). To this end, we crossed the ITCZ three times in the meridional direction. We present the atmospheric and oceanographic measurements collected during ARC in a standardized way to facilitate working with data from different instruments and to make the data easily accessible. This approach is not limited to ARC but could serve as a prototype for future (and past) ship campaigns. We present data from the integrated ship sensors (DShip), a Humidity and Temperature Profiler (HATPRO), a Ceilometer, aerosol instruments (DustTrak, Microtops, and Calitoo), radiosondes, Uncrewed Aircaft Vehicles (UAV), and Conductivity, Temperature, and Depth (CTD) profiles of the upper ocean. We distinguish temporal continuous data (DShip, HATPRO, Ceilometer, DustTrak) from point measurements (radiosondes, UAVs, CTDs, Calitoo, Microtops). To illustrate the data sets provided, we present examples of measurements taken during the three crossings of the ITCZ and during a storm in the Roaring Forties in the South Atlantic at the end of the campaign. All data sets can be downloaded from Köhler et al. (2024a). An overview of all available data sets, including dois, can be found here: https://doi.pangaea.de/10.1594/PANGAEA.966616. For references to the individual data sets, please refer to the data availability section. [ABSTRACT FROM AUTHOR]

Published

2024

9. Polarimetric remote sensing of atmospheric aerosols: Instruments, methodologies, results, and perspectives

Author

Dubovik, Oleg, Li, Zhengqiang, Mishchenko, Michael I., Tanré, Didier, Karol, Yana, Bojkov, Bojan, Cairns, Brian, Diner, David J., Espinosa, W. Reed, Goloub, Philippe, Gu, Xingfa, Hasekamp, Otto, Hong, Jin, Hou, Weizhen, Knobelspiesse, Kirk D., Landgraf, Jochen, Li, Li, Litvinov, Pavel, Liu, Yi, Lopatin, Anton, Marbach, Thierry, Maring, Hal, Martins, Vanderlei, Meijer, Yasjka, Milinevsky, Gennadi, Mukai, Sonoyo, Parol, Frederic, Qiao, Yanli, Remer, Lorraine, Rietjens, Jeroen, Sano, Itaru, Stammes, Piet, Stamnes, Snorre, Sun, Xiaobing, Tabary, Pierre, Travis, Larry D., Waquet, Fabien, Xu, Feng, Yan, Changxiang, and Yin, Dekui

Published

2019

10. Monitoring the impact of forest changes on carbon uptake with solar-induced fluorescence measurements from GOME-2A and TROPOMI for an Australian and Chinese case study.

Author

Anema, Juliëtte C. S., Boersma, Klaas Folkert, Stammes, Piet, Koren, Gerbrand, Woodgate, William, Köhler, Philipp, Frankenberg, Christian, and Stol, Jacqui

Subjects

FOREST monitoring, FLUORESCENCE, WATER supply, FOREST soils

Abstract

Reliable and robust monitoring tools are crucial to assess the effectiveness of land mitigation techniques (LMTs) in enhancing carbon uptake, enabling informed decision making by policymakers. This study, addressing one of the scientific goals of the EU Horizon 2020 Land Use Based Mitigation for Resilient Climate Pathways (LANDMARC) project, examines the feasibility of using satellite solar-induced fluorescence (SIF) in combination with other satellite data as a monitoring proxy to evaluate the effects of LMTs on carbon uptake. Two distinct cases are explored: (1) instantaneous vegetation destruction caused by a 2019 eucalyptus wildfire in southeast Australia and (2) gradual forest gain resulting from reforestation efforts in northern China in 2007–2012. The cases are monitored using SIF from the TROPOspheric Monitoring Instrument (TROPOMI) and Global Ozone Monitoring Experiment-2A (GOME-2A), respectively. Comparing the temporal variability in SIF across the affected areas and nearby reference areas reveals that vegetation dynamics changed as a consequence of the land-use changes in both cases. Specifically, in the Australia case, TROPOMI demonstrated an immediate reduction in the SIF signal of 0.6 mW m -2 sr -1 nm -1 (- 72 %) over the eucalypt forest right after the fire. Exploiting the strong correspondence between TROPOMI SIF and gross primary productivity (GPP) at the nearby representative eddy covariance Tumbarumba site and through the FluxSat product, we estimate that the Australian fire led to a loss in GPP of 130–200 GgC in the first 8 months after the fire. Over the northern Chinese provinces of Gansu, Shaanxi, Sichuan, Chongqing, and Shanxi, we report an increase in GOME-2A summertime SIF of 0.1–0.2 mW m -2 sr -1 nm -1 , coinciding with reforestation efforts between 2007 and 2012. This increase in the SIF signal is likely driven by a combination of increasingly favourable natural conditions and by the reforestation effort itself. A multivariate model that takes into account growth factors such as water availability and maximum temperature as well as satellite-derived forest-cover data explains the observed variability in GOME-2A SIF in the Chinese case reasonably well (R2=0.72). The model suggests that increases in both forest cover and soil moisture have led, in step, to the observed increase in vegetation activity over northern China. In that region, for every 100 km 2 of additional forest cover, SIF increases by 0.1 mW m -2 sr -1 nm -1 between 2007 and 2012. Our study highlights that the use of satellite-based SIF, together with supporting in situ, modelled, and satellite data, allows us to monitor the impact of LMT implementation on regional carbon uptake as long as the scale of the LMT is of sufficient spatial extent. [ABSTRACT FROM AUTHOR]

Published

2024

11. Cancellation of cloud shadow effects in the absorbing aerosol index retrieval algorithm of TROPOMI.

Author

Trees, Victor J. H., Wang, Ping, Stammes, Piet, Tilstra, Lieuwe G., Donovan, David P., and Siebesma, A. Pier

Subjects

BIG data, AEROSOLS, ALGORITHMS, ALBEDO, RADIATIVE transfer, AIR quality, PHASE-shifting interferometry

Abstract

Cloud shadows can be detected in the radiance measurements of the TROPOMI instrument on board the Sentinel-5P satellite due to its high spatial resolution, and could possibly affect its air quality products. The cloud shadow induced signatures are, however, not always apparent and may depend on various cloud and scene parameters. Hence, the quantification of the cloud shadow impact requires the analysis of large data sets. Here we use the cloud shadow detection algorithm DARCLOS to detect cloud shadow pixels in the TROPOMI absorbing aerosol index (AAI) product over Europe during 8 months. For every shadow pixel, we automatically select cloud- and shadow-free neighbour pixels, in order to estimate the cloud shadow induced signature. In addition, we simulate the measured cloud shadow impact on the AAI with our newly developed 3D radiative transfer algorithm MONKI. Both the measurements and simulations show that the average cloud shadow impact on the AAI is close to zero (0.06 and 0.16, respectively). However, the top-of-atmosphere reflectance ratio between 340 and 380 nm, which is used to compute the AAI, is significantly increased in 95 % of the shadow pixels. So, cloud shadows are bluer than surrounding non-shadow pixels. Our simulations explain that the traditional AAI formula intrinsically already corrects for this cloud shadow effect, via the lower retrieved scene albedo. This cancellation of cloud shadow signatures is not always perfect, sometimes yielding second order low and high biases in the AAI which we also successfully reproduce with our simulations. We show that the magnitude of those second order cloud shadow effects depends on various cloud parameters which are difficult to determine for the shadows measured with TROPOMI. We conclude that a potential cloud shadow correction strategy for the TROPOMI AAI would therefore be complicated if not unnecessary. [ABSTRACT FROM AUTHOR]

Published

2024

12. Assessment of the spectral misalignment effect (SMILE) on EarthCARE's Multi-Spectral Imager aerosol and cloud property retrievals.

Author

Docter, Nicole, Hünerbein, Anja, Donovan, David P., Preusker, Rene, Fischer, Jürgen, Meirink, Jan Fokke, Stammes, Piet, and Eisinger, Michael

Subjects

AEROSOLS, GAS absorption & adsorption, SMILING, ICE clouds, WATER vapor, WEATHER

Abstract

The Multi-Spectral Imager (MSI) on board the Earth Cloud, Aerosol and Radiation Explorer (EarthCARE) will provide horizontal information about aerosols and clouds. These measurements are needed to extend vertical cloud and aerosol property information, which is obtained from EarthCARE's active sensors, in order to obtain a full three-dimensional view of cloud and aerosol conditions. Mesoscale weather systems, in particular, will be characterized. The discovery of a non-compliance of the MSI visible–near-infrared–shortwave infrared (VNS) camera's visible (VIS) and shortwave infrared (SWIR1) channels regarding a spectral central wavelength (CWVL) shift across-track of up to 14 nm (VIS) and 20 nm (SWIR1) led to the need for an analysis regarding its impact on MSI Level-2A aerosol and cloud products. A significant influence of the spectral misalignment effect (SMILE) on MSI retrievals is identified due to the spectral variation in gas absorption, surface reflectance, and aerosol and cloud properties within the spectral ranges of these MSI bands. For example, the VIS channel is positioned in close proximity to the red edge of green vegetation and is impacted by residual absorption of water vapor and ozone. Small central wavelength variations introduce uncertainties due to the rapid change in surface reflectance for conditions with low optical thickness. The present central wavelength shift in the VIS towards shorter wavelengths than at nadir introduces a relative error in transmission of up to 3.3 % due to the increasing influence of water vapor and ozone absorption. We found relative errors in the top-of-atmosphere (TOA) signal due to the SMILE of up to 30 % for low optical thickness over a land surface in that band. Since the magnitude of the impact strongly depends on the underlying surface and atmospheric conditions, we conclude that accounting for the SMILE in Level-2 retrievals or correcting the Level-1 signal will improve MSI aerosol and cloud product quality. [ABSTRACT FROM AUTHOR]

Published

2024

13. The Antarctic stratospheric nitrogen hole: Southern Hemisphere and Antarctic springtime total nitrogen dioxide and total ozone variability as observed by Sentinel-5p TROPOMI.

Author

de Laat, Adrianus, van Geffen, Jos, Stammes, Piet, van der A, Ronald, Eskes, Henk, and Veefkind, J. Pepijn

Subjects

OZONE layer, NITROGEN dioxide, OZONE, POLAR vortex, OZONE layer depletion, NITROGEN oxides, PHASE space

Abstract

Denitrification within the stratospheric vortex is a crucial process for Antarctic ozone hole formation, resulting in an analogous stratospheric "nitrogen hole". Sedimentation of large nitric acid trihydrate polar stratospheric cloud particles within the Antarctic polar stratospheric vortex that form during winter depletes the inner vortex of nitrogen oxides. Here, 2018–2021 daily TROPOspheric Monitoring Instrument (TROPOMI) measurements are used for the first time for a detailed characterization of this nitrogen hole. Nitrogen dioxide total columns exhibit strong spatiotemporal and seasonal variations associated with photochemistry as well as transport and mixing processes. Combined with total ozone column data two main regimes are identified: inner-vortex ozone- and nitrogen-dioxide-depleted air and outer-vortex air enhanced in ozone and nitrogen dioxide. Within the vortex total ozone and total stratospheric nitrogen dioxide are strongly correlated, which is much less evident outside of the vortex. Connecting the two main regimes is a third regime of coherent patterns in the total nitrogen dioxide column–total ozone column phase space – defined here as "mixing lines". These mixing lines exist because of differences in three-dimensional variations of nitrogen dioxide and ozone, thereby providing information about vortex dynamics and cross-vortex edge mixing. On the other hand, interannual variability of nitrogen dioxide–total ozone characteristics is rather small except in 2019 when the vortex was unusually unstable. Overall, the results show that daily stratospheric nitrogen dioxide column satellite measurements provide an innovative means for characterizing polar stratospheric denitrification processes, vortex dynamics, and long-term monitoring of Antarctic ozone hole conditions. [ABSTRACT FROM AUTHOR]

Published

2024

14. A directional surface reflectance climatology determined from TROPOMI observations.

Author

Tilstra, Lieuwe G., de Graaf, Martin, Trees, Victor J. H., Litvinov, Pavel, Dubovik, Oleg, and Stammes, Piet

Subjects

CLIMATOLOGY observations, SURFACE of the earth, DATABASES, CLIMATOLOGY, REFLECTANCE

Abstract

In this paper, we introduce a spectral surface reflectivity climatology based on observations made by TROPOMI on board the Sentinel-5P satellite. The database contains the directionally dependent Lambertian-equivalent reflectivity (DLER) of the Earth's surface for 21 wavelength bands ranging from 328 to 2314 nm and for each calendar month. The spatial resolution of the database grid is 0.125° × 0.125°. A recently developed cloud shadow detection technique is implemented to avoid dark scenes due to cloud shadow. In the database, the anisotropy of the surface reflection is described using a third-order parameterisation of the viewing angle dependence. The viewing angle dependence of the DLER is analysed globally and for a selection of surface type regions. The dependence is found to agree with the viewing angle dependence found in the GOME-2 surface DLER database. Differences exist, related to the actual solar position. On average, the viewing angle dependence in TROPOMI DLER is weaker than for GOME-2 DLER, but still important. Validation of the new database was first performed by comparison of the non-directional TROPOMI surface LER with heritage LER databases based on GOME-1 , OMI, SCIAMACHY, and GOME-2 data. Agreement was found within 0.002–0.02 in the UV-VIS (below 500 nm), up to 0.003 in the NIR (670–772 nm), and below 0.001 in the short-wave infrared (SWIR) (2314 nm). These performance numbers are dominated by the performance over ocean, but they are in most cases also representative for land surfaces. For the validation of the directional TROPOMI surface DLER, we made use of comparison with the MODIS surface bi-directional reflectance distribution function (BRDF) for a selection of surface type regions. In all cases the DLER performed significantly better than the traditional LER, and we found good agreement with the MODIS surface BRDF. The TROPOMI surface DLER database is a clear improvement on previous surface albedo databases and can be used as input not only for satellite retrievals from TROPOMI observations, but also for retrievals from observations from other polar-orbiting satellite instruments provided that their equator crossing time is close to that of TROPOMI. The algorithm that is introduced in this paper can be used for the retrieval of surface reflectivity climatologies from other polar satellite missions as well, including Ocean and Land Colour Instrument (OLCI) on the Sentinel-3 satellites, Sentinel-5, and Multi-viewing Multi-channel Multi-polarisation imager (3MI) on the MetOp-SG-A1 satellite to be launched in 2025, as well as the future CO2M mission. [ABSTRACT FROM AUTHOR]

Published

2024

15. Aerosol Shortwave Radiative Heating and Cooling by the 2017 and 2023 Chilean Wildfire Smoke Plumes

Author

de Graaf, Martin, primary, Tilstra, L. Gijsbert, additional, and Stammes, Piet, additional

Published

2023

16. Assessment of the Spectral MIsaLignment Effect (SMILE) on EarthCARE’s Multi-Spectral Imager aerosol and cloud property retrievals

Author

Docter, Nicole, primary, Hünerbein, Anja, additional, Donovan, David Patrick, additional, Preusker, Rene, additional, Fischer, Jürgen, additional, Meirink, Jan Fokke, additional, Stammes, Piet, additional, and Eisinger, Michael, additional

Published

2023

17. A directional surface reflectance climatology determined from TROPOMI observations

Author

Tilstra, Lieuwe G., primary, de Graaf, Martin, additional, Trees, Victor, additional, Litvinov, Pavel, additional, Dubovik, Oleg, additional, and Stammes, Piet, additional

Published

2023

18. Supplementary material to "A directional surface reflectance climatology determined from TROPOMI observations"

Author

Tilstra, Lieuwe G., primary, de Graaf, Martin, additional, Trees, Victor, additional, Litvinov, Pavel, additional, Dubovik, Oleg, additional, and Stammes, Piet, additional

Published

2023

19. Comparison of Cloud Parameters from GOME-2 and Assessment of Cloud Impact on Tropospheric NO2 and HCHO Retrievals

Author

Argyrouli, Athina, primary, Lutz, Ronny, additional, Romahn, Fabian, additional, Molina García, Víctor, additional, Loyola, Diego, additional, Seo, Sora, additional, Valks, Pieter, additional, De Smedt, Isabelle, additional, Boersma, Folkert, additional, Tilstra, Lieuwe Gijsbert, additional, Stammes, Piet, additional, and Compernolle, Steven, additional

Published

2023

20. Monitoring the regional impact of forest loss and gain on carbon uptake with solar-induced fluorescence measurements from the GOME-2A and TROPOMI sensors

Author

Global Ecohydrology and Sustainability, Environmental Sciences, Anema, Juliëtte C. S., Boersma, Klaas Folkert, Stammes, Piet, Koren, Gerbrand, Woodgate, William, Köhler, Philipp, Frankenberg, Christian, Stol, Jacqui, Global Ecohydrology and Sustainability, Environmental Sciences, Anema, Juliëtte C. S., Boersma, Klaas Folkert, Stammes, Piet, Koren, Gerbrand, Woodgate, William, Köhler, Philipp, Frankenberg, Christian, and Stol, Jacqui

Published

2023

21. Assessment of the Spectral MIsaLignment Effect (SMILE) on EarthCARE's Multi-Spectral Imager aerosol and cloud property retrievals.

Author

Docter, Nicole, Hünerbein, Anja, Donovan, David Patrick, Preusker, Rene, Fischer, Jürgen, Meirink, Jan Fokke, Stammes, Piet, and Eisinger, Michael

Subjects

AEROSOLS, GAS absorption & adsorption, SMILING, WATER vapor, ICE clouds, WEATHER

Abstract

The Multi-spectral Imager (MSI) on board the Earth Cloud, Aerosol and Radiation Explorer (EarthCARE) will provide horizontal information about aerosols and clouds. These measurements are needed to extend vertical cloud and aerosol property information, which are obtained from EarthCARE's active sensors, in order to obtain a full three dimensional view on cloud and aerosol conditions. Especially, meso-scale weather systems will be characterized. The discovery of a non-compliance of the MSI VNS camera's visible (VIS) and shortwave-infrared (SWIR1) channels regarding a spectral central wavelength (CWVL) shift across track of up to 14 nm (VIS) and 20 nm (SWIR1), led to the need for an analysis regarding its impact on MSI Level 2A aerosol and cloud products. A significant influence of the Spectral MIsaLignment Effect (SMILE) on MSI retrievals is identified due to the spectral variation of gas absorption, surface reflectance as well as aerosol and cloud properties within the spectral ranges of these MSI bands. For example, the VIS channel is positioned in close proximity to the red edge of green vegetation and is impacted by residual absorption of water vapour and ozone. Small central wavelength variations introduce uncertainties due to the rapid change in surface reflectance for conditions with low optical thickness. The present central wavelength shift in the VIS towards shorter wavelengths than at nadir introduces a relative error in transmission of up to 3.3 % due to the increasing influence of water vapour and ozone absorption. We found relative errors in the TOA signal due to the SMILE of up to 30 % for low optical thickness over a land surface in that band. Since the magnitude of the impact strongly depends on the underlying surface and atmospheric conditions, we conclude that accounting for the SMILE in Level 2 retrievals or correcting the Level 1 signal will improve MSI aerosol and cloud product quality. [ABSTRACT FROM AUTHOR]

Published

2023

22. A directional surface reflectance climatology determined from TROPOMI observations.

Author

Tilstra, Lieuwe G., de Graaf, Martin, Trees, Victor J. H., Litvinov, Pavel, Dubovik, Oleg, and Stammes, Piet

Subjects

CLIMATOLOGY observations, SURFACE of the earth, CLIMATOLOGY, DATABASES, REFLECTANCE

Abstract

In this paper we introduce a spectral surface reflectivity climatology based on observations made by the TROPOMI instrument on board the Sentinel-5P satellite. The database contains the directionally dependent Lambertian-equivalent reflectivity (DLER) of the Earth's surface for 21 wavelength bands ranging from 328nm to 2314nm and for each calendar month. The spatial resolution of the database grid is 0.125° × 0.125°. A recently developed cloud shadow detection technique is implemented to avoid dark scenes due to cloud shadow. In the database, the anisotropy of the surface reflection is described using a third-order parameterisation of the viewing angle dependence. The viewing angle dependence of the DLER is analysed globally and for a selection of surface type regions. The dependence is found to agree with the viewing angle dependence found in the GOME-2 surface DLER database. Differences exist, related to the actual solar position. On average, the viewing angle dependence in TROPOMI DLER is weaker than for GOME-2 DLER, but still important. Validation of the new database was first performed by comparison of the non-directional TROPOMI surface LER with heritage LER databases based on GOME-1, OMI, SCIAMACHY, and GOME-2 data. Agreement was found within 0.002-0.02 in the UV-VIS (below 500nm), up to 0.003 in the NIR (670-772nm), and below 0.001 in the SWIR (2314nm). These performance numbers are dominated by the performance over ocean, but they are in most cases also representative for land surfaces. For the validation of the directional TROPOMI surface DLER we made use of comparison with MODIS surface BRDF for a selection of surface type regions. In all cases the DLER performed significantly better than the traditional LER and we found good agreement with MODIS surface BRDF. The TROPOMI surface DLER database is a clear improvement on previous surface albedo databases and can be used as input not only for satellite retrievals from TROPOMI observations, but also for retrievals from observations from other polarorbiting satellite instruments provided that their equator crossing time is close to that of TROPOMI. The algorithm that is introduced in this paper can be used for the retrieval of surface reflectivity climatologies from other polar satellite missions as well, including OLCI on the Sentinel-3 satellites, Sentinel-5 and 3MI on the MetOp-SG-A1 satellite to be launched in 2025, and the future CO2M mission. [ABSTRACT FROM AUTHOR]

Published

2023

23. The Antarctic stratospheric Nitrogen Hole: Southern Hemisphere and Antarctic springtime total nitrogen dioxide and total ozone variability as observed in Sentinel-5p TROPOMI data.

Author

Laat, Adrianus de, Geffen, Jos van, Stammes, Piet, A, Ronald van der, Eskes, Henk, and Veefkind, Pepijn

Subjects

OZONE layer, NITROGEN dioxide, OZONE, OZONE layer depletion, PHASE space, NITROGEN

Abstract

Denitrification of the stratospheric vortex is a crucial process for the Antarctic Ozone Hole formation resulting in an analogous stratospheric "Nitrogen Hole". Here, 2018–2021 daily TROPOMI measurements are used for the first time for a detailed characterization of this Nitrogen Hole. Nitrogen dioxide total columns exhibit strong spatiotemporal and seasonal variations associated with both photochemistry as well as transport and mixing processes. Combined with total ozone column data two main regimes are identified: inner-vortex ozone and nitrogen dioxide depleted air and outer-vortex air enhanced in ozone and nitrogen dioxide. Within the vortex total ozone and total stratospheric nitrogen dioxide are strongly correlated which is much less evident outside of the vortex. Connecting both main regimes are what is defined here as "mixing lines", a third regime of coherent patterns in the total nitrogen dioxide column – total ozone column phase space. These mixing lines exist because of differences in three dimensional variations of nitrogen dioxide and ozone thereby providing information about vortex dynamics and cross-vortex edge mixing. On the other hand, interannual variability of nitrogen dioxide – total ozone characteristics are rather small except in 2019 when the vortex was unusually unstable. Overall, the results show that daily stratospheric nitrogen dioxide column satellite measurements provide an innovative means for characterizing and Polar stratospheric denitrification processes and vortex dynamics and potentially long term monitoring if the total nitrogen column data record is extended with past satellite observations. [ABSTRACT FROM AUTHOR]

Published

2023

24. The Antarctic stratospheric Nitrogen Hole: Southern Hemisphere and Antarctic springtime total nitrogen dioxide and total ozone variability as observed in Sentinel-5p TROPOMI data.

Author

de Laat, Adrianus, van Geffen, Jos, Stammes, Piet, van der A., Ronald, Eskes, Henk, and Veefkind, J. Pepijn

Abstract

Denitrification of the stratospheric vortex is a crucial process for the Antarctic Ozone Hole formation resulting in an analogous stratospheric “Nitrogen Hole”. Here, 2018-2021 daily TROPOMI measurements are used for the first time for a detailed characterization of this Nitrogen Hole. Nitrogen dioxide total columns exhibit strong spatiotemporal and seasonal variations associated with both photochemistry as well as transport and mixing processes. Combined with total ozone column data two main regimes are identified: inner-vortex ozone and nitrogen dioxide depleted air and outer-vortex air enhanced in ozone and nitrogen dioxide. Within the vortex total ozone and total stratospheric nitrogen dioxide are strongly correlated which is much less evident outside of the vortex. Connecting both main regimes are what is defined here as “mixing lines”, a third regime of coherent patterns in the total nitrogen dioxide column - total ozone column phase space. These mixing lines exist because of differences in three dimensional variations of nitrogen dioxide and ozone thereby providing information about vortex dynamics and cross-vortex edge mixing. On the other hand, interannual variability of nitrogen dioxide – total ozone characteristics are rather small except in 2019 when the vortex was unusually unstable. Overall, the results show that daily stratospheric nitrogen dioxide column satellite measurements provide an innovative means for characterizing polar stratospheric denitrification processes, vortex dynamics and potentially long term monitoring if the total nitrogen column data record is extended with past satellite observations. [ABSTRACT FROM AUTHOR]

Published

2023

25. Monitoring the regional impact of forest loss and gain on carbon uptake with solar-induced fluorescence measurements from the GOME-2A and TROPOMI sensors.

Author

Anema, Juliëtte C. S., Boersma, Klaas Folkert, Stammes, Piet, Koren, Gerbrand, Woodgate, William, Köhler, Philipp, Frankenberg, Christian, and Stol, Jacqui

Subjects

FLUORESCENCE, WATER supply, VEGETATION dynamics, REFORESTATION, CARBON

Abstract

Reliable and robust monitoring tools are crucial to assess the effectiveness of land mitigation techniques (LMTs) in enhancing carbon uptake, enabling informed decision-making by policymakers. This study, addressing one of the scientific goals of the EU H2020 LANDMARC project, examines the feasibility of using satellite solar-induced fluorescence (SIF), in combination with other satellite data, as a monitoring proxy to evaluate the effects of LMTs on carbon uptake. Two distinct cases are explored: (1) instantaneous vegetation destruction caused by a 2019 Eucalyptus wildfire in south-east Australia, and, (2) gradual forest gain resulting from reforestation efforts in northern China over 2007–2012. The cases are monitored using TROPOMI and GOME-2A SIF, respectively. Comparing the temporal variability in SIF across the affected and nearby reference areas reveals that vegetation dynamics changed as a consequence of the land use changes in both cases. Specifically, in the Australia case, TROPOMI demonstrated an immediate reduction in SIF signal of 0.6 mW m−2 sr−1 nm−1 (−72 %) over the Eucalypt Forest right after the fire. Exploiting the strong correspondence between TROPOMI SIF and gross primary productivity (GPP) at the nearby eddy-covariance Tumbarumba site and through the FluxSat product, we estimate that the fire led to a loss in GPP of 130–200 GgC in the first eight months after the fire. Over the northern Chinese provinces of Gansu, Shaanxi, Sichuan, Chongqing and Shanxi, we report an increase in GOME-2A summertime SIF of 0.1–0.2 mW m−2 sr−1 nm−1 coinciding with reforestation efforts between 2007 and 2012. This increase in SIF signal is likely driven by a combination of increasingly favourable natural conditions and the reforestation effort itself. A multivariate model that takes into account growth factors such as water availability and maximum temperature as well as satellite-derived forest cover data explains the observed variability in GOME-2A SIF in the Chinese case reasonably well (R2=0.72). The model suggests that both increases in forest cover as well as in soil moisture have led, in step, to the observed increase in vegetation activity over northern China. In that region, for every 100 km2 of additional forest cover, SIF increases by 0.1 mW m−2 sr−1 nm−1 between 2007 and 2012. Our study highlights that the combined use of satellite-based SIF, together with supporting in situ, modelled and satellite-data, allows to monitor the impact of LMT implementation on regional carbon uptake as long as the scale of the LMT is of sufficient spatial extent. [ABSTRACT FROM AUTHOR]

Published

2023

26. 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

27. Advances in Lidar Observations for Airborne Hazards for Aviation in the Framework of the EUNADICS-AV Project

Author

Apituley Arnoud, Mona Lucia, Papagiannopoulos Nikolas, Rufenacht Rolf, Wagenaar Saskia, Stammes Piet, de Laat Jos, de Cerff Wim Som, de Haij Marijn, Marchese Francesco, Falconieri Alfredo, Haefele Alexander, and Hervo Maxime

Subjects

Physics, QC1-999

Abstract

The vulnerability of the (European) aviation system to the airborne hazards was evident during the Eyjafjallajökull volcanic eruption in 2010. For support of Air Traffic Control (ATC) many observations of the event were available from satellites, ground based instruments and airborne platforms, at pan-European scale. However, efficient use of the data for ATC proved difficult mainly due to sub-optimal aggregation and integrated assessment of the available information in near-real-time. The project EUNADICS-AV (European Natural Disaster Coordination and Information System for Aviation) aims to close this gap. The observational component of the project will make existing data products for airborne hazards more accessible, visible and used, and to foster tailored product development. Once assimilated into models and integrated in the EUNADICS-AV Data Portal these data can be the base to efficiently improve European airspace resilience to airborne hazards. Since 2010 new data products have become available specifically for for airborne hazard alerting and monitoring together with specific tailored products designed for replying to user needs and recommendations. This paper describes the EUNADICS-AV approach and will focus on the role of operational and research grade ground based lidars.

Published

2020

28. Polarimetric Remote Sensing of Atmospheric Aerosols: Instruments, Methodologies, Results, and Perspectives

Author

Dubovik, Oleg, Li, Zhengqiang, Mishchenko, Michael I, Tanre, Didier, Karol, Yana, Bojkov, Bojan, Cairns, Brian, Diner, David J, Espinosa, W. Reed, Goloub, Philippe, Gu, Xingfa, Hasekamp, Otto, Hong, Jin, Hou, Weizhen, Knobelspiesse, Kirk D, Landgraf, Jochen, Litvinov, Pavel, Liu, Yi, Lopatin, Anton, Marbach, Thierry, Maring, Hal, Martins, Vanderlei, Meijer, Yasjka, Milinevsky, Gennadi, Mukai, Sonoyo, Parol, Frederic, Qiao, Yanli, Remer, Lorraine, Rietjens, Jeroen, Sano, Itaru, Stammes, Piet, Stamnes, Snorre A, Sun, Xiaobing, Tabary, Pierre, Travis, Larry D, Waquet, Fabien, Xu, Feng, Yan, Changxiang, and Yin, Dekui

Subjects

Earth Resources And Remote Sensing, Instrumentation And Photography

Abstract

Polarimetry is one of the most promising types of remote sensing for improved characterization of atmospheric aerosol. Indeed, aerosol particles constitute a highly variable atmospheric component characterized by a large number of parameters describing particle sizes, morphologies (including shape and internal structure), absorption and scattering properties, amounts, horizontal and vertical distribution, etc. Reliable monitoring of all these parameters is very challenging, and therefore the aerosol effects on climate and environment are considered to be among the most uncertain factors in climate and environmental research. In this regard, observations that provide both the angular distribution of the scattered atmospheric radiation as well as its polarization state at multiple wavelengths covering the UV–SWIR spectral range carry substantial implicit information on the atmospheric composition. Therefore, high expectations in improving aerosol characterization are associated with detailed passive photopolarimetric observations. The critical need to use space-borne polarimetry for global accurate monitoring of detailed aerosol properties was first articulated in the late 1980s and early 1990s. By now, several orbital instruments have already provided polarization observations from space, and a number of advanced missions are scheduled for launch in the coming years by international and national space agencies. The first and most extensive record of polarimetric imagery was provided by POLDER-I, POLDER-II, and POLDER/PARASOL multi-angle multi-spectral polarization sensors. Polarimetric observations with the POLDER-like design intended for collecting extensive multi-angular multi-spectral measurements will be provided by several instruments, such as the MAI/TG-2, CAPI/TanSat, and DPC/GF-5 sensors recently launched by the Chinese Space Agency. Instruments such as the 3MI/MetOp-SG, MAIA, SpexOne and HARP2 on PACE, POSP, SMAC, PCF, DPC–Lidar, ScanPol and MSIP/Aerosol-UA, MAP/Copernicus CO2 Monitoring, etc. are planned to be launched by different space agencies in the coming decade. The concepts of these future instruments, their technical designs, and the accompanying algorithm development have been tested intensively and analyzed using diverse airborne prototypes. Certain polarimetric capabilities have also been implemented in such satellite sensors as GOME-2/MetOp and SGLI/GCOM-C.

Published

2018

29. Recent instruments and algorithms for passive shortwave remote sensing

Author

Remer, Lorraine A., Brogniez, Colette, Cairns, Brian, Hsu, N. Christina, Kahn, Ralph, Stammes, Piet, Tanré, Didier, Torres, Omar, Lenoble, Jacqueline, editor, Remer, Lorraine, editor, and Tanre, Didier, editor

Published

2013

30. Data Quality and Validation of Satellite Measurements of Tropospheric Composition

Author

Piters, Ankie J. M., Buchmann, Brigitte, Brunner, Dominik, Cohen, Ronald C., Lambert, Jean-Christopher, de Leeuw, Gerrit, Stammes, Piet, van Weele, Michiel, Wittrock, Folkard, Burrows, John P., editor, Borrell, Peter, editor, and Platt, Ulrich, editor

Published

2011

31. Introduction of the DISAMAR radiative transfer model: determining instrument specifications and analysing methods for atmospheric retrieval (version 4.1.5)

Author

de Haan, Johan F., primary, Wang, Ping, additional, Sneep, Maarten, additional, Veefkind, J. Pepijn, additional, and Stammes, Piet, additional

Published

2022

32. Comparison of Cloud Parameters from GOME-2 and Assessment of Cloud Impact on Tropospheric NO2 and HCHO Retrievals.

Author

Argyrouli, Athina, Lutz, Ronny, Romahn, Fabian, García, Víctor Molina, Loyola, Diego, Seo, Sora, Valks, Pieter, De Smedt, Isabelle, Boersma, Folkert, Tilstra, Lieuwe Gijsbert, Stammes, Piet, and Compernolle, Steven

Subjects

CLOUDS, OXYGEN, TRACE gases, AIR quality, CLIMATE change

Abstract

In recent decades, there has been an increasing interest in making use of satellite measurements for identifying trends in atmospheric composition and climate. Instruments like GOME-2 and TROPOMI are dedicated to air-quality and global trace gas monitoring. For the accurate retrieval of columnar information of the trace gases, cloud correction is necessary. This work is meant to examine the quality of the GOME-2 operational cloud product from AC SAF and to propose enhancements of the current dataset to improve the retrieval of the NO2 and HCHO tropospheric gases. [ABSTRACT FROM AUTHOR]

Published

2023

33. DARCLOS: a cloud shadow detection algorithm for TROPOMI

Author

Trees, V.J.H. (author), Wang, Ping (author), Stammes, Piet (author), Tilstra, Lieuwe G. (author), Donovan, D.P. (author), Siebesma, A.P. (author), Trees, V.J.H. (author), Wang, Ping (author), Stammes, Piet (author), Tilstra, Lieuwe G. (author), Donovan, D.P. (author), and Siebesma, A.P. (author)

Abstract

Cloud shadows are observed by the TROPOMI satellite instrument as a result of its high spatial resolution compared to its predecessor instruments. These shadows contaminate TROPOMI's air quality measurements, because shadows are generally not taken into account in the models that are used for aerosol and trace gas retrievals. If the shadows are to be removed from the data, or if shadows are to be studied, an automatic detection of the shadow pixels is needed. We present the Detection AlgoRithm for CLOud Shadows (DARCLOS) for TROPOMI, which is the first cloud shadow detection algorithm for a spaceborne spectrometer. DARCLOS raises potential cloud shadow flags (PCSFs), actual cloud shadow flags (ACSFs), and spectral cloud shadow flags (SCSFs). The PCSFs indicate the TROPOMI ground pixels that are potentially affected by cloud shadows based on a geometric consideration with safety margins. The ACSFs are a refinement of the PCSFs using spectral reflectance information of the PCSF pixels and identify the TROPOMI ground pixels that are confidently affected by cloud shadows. Because we find indications of the wavelength dependence of cloud shadow extents in the UV, the SCSF is a wavelength-dependent alternative for the ACSF at the wavelengths of TROPOMI's air quality retrievals. We validate the PCSF and ACSF with true-colour images made by the VIIRS instrument on board Suomi NPP orbiting in close proximity to TROPOMI on board Sentinel-5P. We find that the cloud evolution during the overpass time difference between TROPOMI and VIIRS complicates this validation strategy, implicating that an alternative cloud shadow detection approach using co-located VIIRS observations could be problematic. We conclude that the PCSF can be used to exclude cloud shadow contamination from TROPOMI data, while the ACSF and SCSF can be used to select pixels for the scientific analysis of cloud shadow effects., Atmospheric Remote Sensing

Published

2022

34. DARCLOS: a cloud shadow detection algorithm for TROPOMI

Author

Trees, Victor J. H., primary, Wang, Ping, additional, Stammes, Piet, additional, Tilstra, Lieuwe G., additional, Donovan, David P., additional, and Siebesma, A. Pier, additional

Published

2022

35. DARCLOS: a cloud shadow detection algorithm for TROPOMI

Author

Trees, Victor, primary, Wang, Ping, additional, Stammes, Piet, additional, Tilstra, Lieuwe G., additional, Donovan, David P., additional, and Siebesma, A. Pier, additional

Published

2021

36. EUNADICS-AV early warning system dedicated to supporting aviation in the case of a crisis from natural airborne hazards and radionuclide clouds

Author

Brenot, Hugues, primary, Theys, Nicolas, additional, Clarisse, Lieven, additional, van Gent, Jeroen, additional, Hurtmans, Daniel R., additional, Vandenbussche, Sophie, additional, Papagiannopoulos, Nikolaos, additional, Mona, Lucia, additional, Virtanen, Timo, additional, Uppstu, Andreas, additional, Sofiev, Mikhail, additional, Bugliaro, Luca, additional, Vázquez-Navarro, Margarita, additional, Hedelt, Pascal, additional, Parks, Michelle Maree, additional, Barsotti, Sara, additional, Coltelli, Mauro, additional, Moreland, William, additional, Scollo, Simona, additional, Salerno, Giuseppe, additional, Arnold-Arias, Delia, additional, Hirtl, Marcus, additional, Peltonen, Tuomas, additional, Lahtinen, Juhani, additional, Sievers, Klaus, additional, Lipok, Florian, additional, Rüfenacht, Rolf, additional, Haefele, Alexander, additional, Hervo, Maxime, additional, Wagenaar, Saskia, additional, Som de Cerff, Wim, additional, de Laat, Jos, additional, Apituley, Arnoud, additional, Stammes, Piet, additional, Laffineur, Quentin, additional, Delcloo, Andy, additional, Lennart, Robertson, additional, Rokitansky, Carl-Herbert, additional, Vargas, Arturo, additional, Kerschbaum, Markus, additional, Resch, Christian, additional, Zopp, Raimund, additional, Plu, Matthieu, additional, Peuch, Vincent-Henri, additional, Van Roozendael, Michel, additional, and Wotawa, Gerhard, additional

Published

2021

37. Aerosol influence on polarization and intensity in near-infrared O 2 and CO 2 absorption bands observed from space

Author

Boesche, Eyk, Stammes, Piet, and Bennartz, Ralf

Published

2009

38. 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

39. Directionally dependent Lambertian-equivalent reflectivity (DLER) of the Earth's surface measured by the GOME-2 satellite instruments

Author

Tilstra, Lieuwe G., primary, Tuinder, Olaf N. E., additional, Wang, Ping, additional, and Stammes, Piet, additional

Published

2021

40. Restoring the top-of-atmosphere reflectance during solar eclipses: a proof of concept with the UV absorbing aerosol index measured by TROPOMI

Author

Trees, Victor, primary, Wang, Ping, additional, and Stammes, Piet, additional

Published

2021

41. 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

42. Restoring the top-of-atmosphere reflectance during solar eclipses: a proof of concept with the UV Absorbing Aerosol Index measured by TROPOMI

Author

Trees, Victor, Wang, Ping, Stammes, Piet, Trees, Victor, Wang, Ping, and Stammes, Piet

Abstract

During a solar eclipse the solar irradiance reaching the top-of-atmosphere (TOA) is reduced in the Moon shadow. The solar irradiance is commonly measured by Earth observation satellites before the start of the solar eclipse and is not corrected for this reduction, which results in a decrease of the computed TOA reflectances. Consequently, air quality products that are derived from TOA reflectance spectra, such as the ultraviolet (UV) Absorbing Aerosol Index (AAI), are distorted or undefined in the shadow of the Moon. The availability of air quality satellite data in the penumbral and antumbral shadow during solar eclipses, however, is of particular interest to users studying the atmospheric response to solar eclipses. Given the time and location of a point on the Earth's surface, we explain how to compute the obscuration during a solar eclipse taking into account wavelength-dependent solar limb darkening. With the calculated obscuration fractions, we restore the TOA reflectances and the AAI in the penumbral shadow during the annular solar eclipses on 26 December 2019 and 21 June 2020 measured by the TROPOMI/S5P instrument. In the corrected products, the signature of the Moon shadow disappeared, but only if wavelength-dependent solar limb darkening is taken into account. We conclude that the correction method of this paper can be used to detect real AAI rising phenomena during a solar eclipse and has the potential to restore any other product that is derived from TOA reflectance spectra. This would resolve the solar eclipse anomalies in satellite air quality measurements and would allow for studying the effect of the eclipse obscuration on the composition of the Earth's atmosphere from space., Comment: Accepted for publication in Atmospheric Chemistry and Physics

Published

2021

43. EUNADICS-AV early warning system dedicated to supporting aviation in the case of a crisis from natural airborne hazards and radionuclide clouds

Author

Brenot, Hugues, Theys, Nicolas, Clarisse, Lieven, van Gent, Jeroen, Hurtmans, Daniel R., Vandenbussche, Sophie, Papagiannopoulos, Nikolaos, Mona, Lucia, Virtanen, Timo, Uppstu, Andreas, Sofiev, Mikhail, Bugliaro, Luca, Vazquez-Navarro, Margarita, Hedelt, Pascal, Parks, Michelle Maree, Barsotti, Sara, Coltelli, Mauro, Moreland, William, Scollo, Simona, Salerno, Giuseppe, Arnold-Arias, Delia, Hirtl, Marcus, Peltonen, Tuomas, Lahtinen, Juhani, Sievers, Klaus, Lipok, Florian, Rufenacht, Rolf, Haefele, Alexander, Hervo, Maxime, Wagenaar, Saskia, de Cerff, Wim Som, de Laat, Jos, Apituley, Arnoud, Stammes, Piet, Laffineur, Quentin, Delcloo, Andy, Robertson, Lennart, Rokitansky, Carl-Herbert, Vargas, Arturo, Kerschbaum, Markus, Resch, Christian, Zopp, Raimund, Plu, Matthieu, Peuch, Vincent-Henri, Van Roozendael, Michel, Wotawa, Gerhard, Brenot, Hugues, Theys, Nicolas, Clarisse, Lieven, van Gent, Jeroen, Hurtmans, Daniel R., Vandenbussche, Sophie, Papagiannopoulos, Nikolaos, Mona, Lucia, Virtanen, Timo, Uppstu, Andreas, Sofiev, Mikhail, Bugliaro, Luca, Vazquez-Navarro, Margarita, Hedelt, Pascal, Parks, Michelle Maree, Barsotti, Sara, Coltelli, Mauro, Moreland, William, Scollo, Simona, Salerno, Giuseppe, Arnold-Arias, Delia, Hirtl, Marcus, Peltonen, Tuomas, Lahtinen, Juhani, Sievers, Klaus, Lipok, Florian, Rufenacht, Rolf, Haefele, Alexander, Hervo, Maxime, Wagenaar, Saskia, de Cerff, Wim Som, de Laat, Jos, Apituley, Arnoud, Stammes, Piet, Laffineur, Quentin, Delcloo, Andy, Robertson, Lennart, Rokitansky, Carl-Herbert, Vargas, Arturo, Kerschbaum, Markus, Resch, Christian, Zopp, Raimund, Plu, Matthieu, Peuch, Vincent-Henri, Van Roozendael, Michel, and Wotawa, Gerhard

Published

2021

44. EUNADICS early warning system dedicated to support aviation in case of crisis from natural airborne hazard and radionuclide cloud

Author

Brenot, Hugues, primary, Theys, Nicolas, additional, Clarisse, Lieven, additional, van Gent, Jeroen, additional, Hurtmans, Daniel R., additional, Vandenbussche, Sophie, additional, Papagiannopoulos, Nikolaos, additional, Mona, Lucia, additional, Virtanen, Timo, additional, Uppstu, Andreas, additional, Sofiev, Mikhail, additional, Bugliaro, Luca, additional, Vázquez-Navarro, Margarita, additional, Hedelt, Pascal, additional, Parks, Michelle Maree, additional, Barsotti, Sara, additional, Coltelli, Mauro, additional, Moreland, William, additional, Arnold-Arias, Delia, additional, Hirtl, Marcus, additional, Peltonen, Tuomas, additional, Lahtinen, Juhani, additional, Sievers, Klaus, additional, Lipok, Florian, additional, Rüfenacht, Rolf, additional, Haefele, Alexander, additional, Hervo, Maxime, additional, Wagenaar, Saskia, additional, Som de Cerff, Wim, additional, de Laat, Jos, additional, Apituley, Arnoud, additional, Stammes, Piet, additional, Laffineur, Quentin, additional, Delcloo, Andy, additional, Lennart, Robertson, additional, Rokitansky, Carl-Herbert, additional, Vargas, Arturo, additional, Kerschbaum, Markus, additional, Resch, Christian, additional, Zopp, Raimund, additional, Plu, Matthieu, additional, Peuch, Vincent-Henri, additional, Van Roozendael, Michel, additional, and Wotawa, Gerhard, additional

Published

2021

45. Supplementary material to "EUNADICS early warning system dedicated to support aviation in case of crisis from natural airborne hazard and radionuclide cloud"

Author

Brenot, Hugues, primary, Theys, Nicolas, additional, Clarisse, Lieven, additional, van Gent, Jeroen, additional, Hurtmans, Daniel R., additional, Vandenbussche, Sophie, additional, Papagiannopoulos, Nikolaos, additional, Mona, Lucia, additional, Virtanen, Timo, additional, Uppstu, Andreas, additional, Sofiev, Mikhail, additional, Bugliaro, Luca, additional, Vázquez-Navarro, Margarita, additional, Hedelt, Pascal, additional, Parks, Michelle Maree, additional, Barsotti, Sara, additional, Coltelli, Mauro, additional, Moreland, William, additional, Arnold-Arias, Delia, additional, Hirtl, Marcus, additional, Peltonen, Tuomas, additional, Lahtinen, Juhani, additional, Sievers, Klaus, additional, Lipok, Florian, additional, Rüfenacht, Rolf, additional, Haefele, Alexander, additional, Hervo, Maxime, additional, Wagenaar, Saskia, additional, Som de Cerff, Wim, additional, de Laat, Jos, additional, Apituley, Arnoud, additional, Stammes, Piet, additional, Laffineur, Quentin, additional, Delcloo, Andy, additional, Lennart, Robertson, additional, Rokitansky, Carl-Herbert, additional, Vargas, Arturo, additional, Kerschbaum, Markus, additional, Resch, Christian, additional, Zopp, Raimund, additional, Plu, Matthieu, additional, Peuch, Vincent-Henri, additional, Van Roozendael, Michel, additional, and Wotawa, Gerhard, additional

Published

2021

46. Comment on amt-2020-449

Author

Stammes, Piet, primary

Published

2021

47. Validation of the Sentinel-5 Precursor TROPOMI cloud data with Cloudnet, Aura OMI O<sub>2</sub>–O<sub>2</sub>, 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

48. Surface and aerosol retrieval from S5P/TROPOMI: new possibilities and expected performance

Author

Litvinov, Pavel, primary, Dubovik, Oleg, additional, Chen, Cheng, additional, Lopatin, Anton, additional, Lapyonok, Tatyana, additional, Fuertes, David, additional, Bindreiter, Lukas, additional, Lanzinger, Verena, additional, Holter, Christoph, additional, Hangler, Andreas, additional, Aspetsberger, Michael, additional, de Graaf, Martin, additional, Tilstra, Gijsbert, additional, Stammes, Piet, additional, and Retscher, Christian, additional

Published

2021

49. 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

50. Improving cloud retrievals for accurate detection of ship NO2 plumes from S5P-TROPOMI

Author

Rieß, Christoph, primary, Boersma, Folkert, additional, van Vliet, Jasper, additional, Eskes, Henk, additional, van Geffen, Jos, additional, Stammes, Piet, additional, Boot, Wouter, additional, de Laat, Jos, additional, Peters, Wouter, additional, and Veefkind, Pepijn, additional

Published

2021