Aerosol

The Aerosol project provides independently validated, high quality algorithms for processing long-term records of global aerosol properties from European satellite instruments.

About

Aerosol particles in the atmosphere have an important influence on the Earth's radiative balance by directly reflecting sunlight back into space, as well as absorbing some sunlight and converting it into heat. Aerosols also have an impact on climate by acting as cloud condensation nuclei, which alters cloud properties and their radiative effects. Aerosol particles at surface level impact human health, and are associated with disruption to transport (desert dust storms and volcanic eruptions) and can reduce the solar irradiance available for solar power plants.

Objective

The driving objective of the CCI Aerosol project is to provide independently validated, high quality algorithms for processing long-term records of global aerosol properties from European satellite instruments.

The current Aerosol project, running March 2019 to February 2022, focuses on algorithm improvements for the dual view sensor line, in particular the Sentinel-3 SLSTR instrument together with two user case studies (data assimilation for climate services, and science modelling in radiative forcing) and community support (AEROSAT experiments, GEWEX assessment).

The processing of long-term records (6-monthly extensions and complete reprocessing every 2-3 years) has been transferred to the Copernicus Climate Change Service since 2018 within the contracts C3S_312a_Lot5 (October 2016 – September 2018) and C3S_312b_Lot2 (October 2018 – June 2021).

In response to the requirements of the Global Climate Observing System (GCOS) and the AEROCOM international modelling community, the two former phases of the Aerosol have focused on:

Improving and assessing algorithms for total aerosol optical depth
Improving and assessing algorithms for fine / coarse mode aerosol optical depth and for dust optical depth
Improving and assessing algorithms for stratospheric extinction profiles
Testing algorithms for further aerosol quantitates (effective layer height, single scattering albedo / absorbing aerosol optical depth)
Working with the AEROCOM community as a primary user and conducting ten dedicated user case studies on the applicability of those data sets, their strengths and weaknesses.

Aerosol Phase 1 ran July 2010 to February 2014; Phase 2 ran May 2014 to October 2019. Aerosol_cci+ Phase 1 extended from March 2019 to July 2022. A new project under the CCI extension for new research on aerosol ECVs is foreseen from December 2022 to run for 24 months.

Data

The latest global Aerosol_cci products including uncertainties are provided via the CCI Open Data Portal:

Since operational continuation of data (re-)processing has been transfer to the Copernicus Climate Change Service, more recent versions of updated / improved data records (also including successor sensors SLSTR and OLCI) are available at the Copernicus Climate Data Store

Latest mature Aerosol_cci data records

AATSR_ADV and ATSR2_ADV / v2.31 AOD, FMAOD 1995-2012 (FMI)
AATSR_ORAC and ATSR2_ORAC / v4.01 AOD, FMAOD 1995-2012 (Oxford University / RAL)
AATSR_SU and ATSR_SU / v4.3 AOD, FMAOD 1995-2012 (Swansea University)
AATSR and ATSR2 uncertainty-weighted ensemble v2.6 (DLR)
IASI_ULB / v8 Dust AOD 2007-2015 (ULB), available on request
IASI_LMD / v2.1 Dust AOD 2007-2015 (LMD), available on request
IASI_IMARS / v5.2 Dust AOD 2007-2015 (DLR), available on request
IASI_MAPIR / v3.51 Dust AOD 2007-2015 (BIRA), available on request
PARASOL_GRASP v0.08 AOD, FMAOD, SSA 2005-2013, 4 selected regions (LOA), available on request
GOMOS_AERGOM / v3.00 stratospheric extinction 2002-2012 (BIRA)

Additional Aerosol_cci data records

MERIS_ALAMO / v2.2 AOD 1-12 2008, ocean only (ICARE)
Multi-sensor AAI / v1.7 1978-2012 (KNMI, co-funded by Aerosol_cci)
SEVIRI CISAR data set v10 2008 is provided (experimental, available on request), available on request

Main dataset characteristics

The four AATSR data sets are similar in their quality over land to MODIS / MISR but with weaker coverage and less accuracy for high AOD values. The four ATSR-2 data sets cover a historic period observed by few other satellite aerosol sensors.

The four IASI datasets contain a complementary aerosol property (mineral dust AOD).

PARASOL / GRASP provides several consistent aerosol properties within one retrieval: AOD, Fine Mode AOD, Single Scattering Albedo.

GOMOS / AERGOM provides stratospheric extinction profile data sets.

The multi-sensor AAI record provides qualitative information on aerosol absorption.

The MERIS data set provides wider swath width than AATSR (both on-board ENVISAT).

The SEVIRI CISAR algorithm provides hourly AOD.

Key Documents

Nom du document	Version	Date de publication
User Requirements Document (URD)	5.0	-
Product Validation Plan (PVP)	3.0	-
Algorithm Theoretical Basis Document (Swansea Algorithm ATSR)	4.35	-
Algorithm Theoretical Basis Document (Swansea Algorithm SLSTR)	1.1	-
Algorithm Theoretical Basis Document (CISAR Rayference SLSTR)	1.2	-
Algorithm Development Plan / Report	3.0	-
End-to-End ECV Uncertainty Budget (E3UB)	3.0	-
System Specification Document (SSD)	3.0	-
Product User Guide (PUG)	3.0	-
Project Scientific Highlights (PSH)	1.1 (Year 3)	-
CRDP Documentation	3.1	-
Product Validation and Intercomparison Report	3.1	-
Climate Assessment Report	3.1	-

Team

The Aerosol project team is composed of following partners:

Project Coordination

German Aerospace Center (DLR)

Dr. Thomas Popp is science leader and project manager.

EO Expert Team (retrieval development and validation)

Swansea University (SU)

Dr. Peter North and his team are focusing on further improving the SLSTR (and ATSR) retrieval algorithms used in Aerosol_CCI2.
Dr. Yves Govaerts and his team are working on a new SLSTR retrieval based on SEVIRI heritage.

German Aerospace Center (DLR)

Dr. Thomas Popp and his team are working on the validation of aerosol data sets with AERONET and coordinate the AEROSAT network.

Finnish Meteorological Institute (FMI)

Drs. Larisa Sogacheva and Pekka Kolmonen are working on inter-comparisons of aerosol data sets with other satellite-based data sets and support AEROSAT experiments.

Climate Modelling Team

Max-Planck Institute for Meteorology (MPI)

Dr. Stefan Kinne is working on a scientific user case study on using SLSTR (and other) information to constrain radiative forcing and provides links to the AEROCOM modelling community.

European Centre for Medium Range Weather Forecasts (ECMWF)

Drs. Angela Benedetti and Rossana Dragani are working on a user case study for data assimilation of SLSTR aerosol data and linking to the data assimilation / forecasting / climate service communities.

The Aerosol project is rooted deeply into the developments of its predecessor project. Aerosol phase 1 and phase 2 project teams were composed of following partners:

German Aerospace Center (DLR): Drs. Thomas Popp (co science leader, project manager), Miriam Kosmale (dpt. project manager), Lars Klüser (EO experts), Julian Meyer-Arnek (system engineer).
Finnish Meteorological Institute (FMI): Prof. Dr. Gerrit de Leeuw (co science leader), Drs. Larisa Sogacheva, Pekka Kolmonen (EO experts).
Oxford University (UO): Drs. Don Grainger, Adam Povey (EO experts)
Rutherford Appleton Laboratory (RAL): Drs. Caroline Poulson, Gareth Thomas, (EO experts), Richard Siddans (system engineer)
Swansea University (SU): Drs. Peter North, Andreas Heckel (EO experts)
University of Bremen (UB): Drs. Marco Vountas, Linlu Mei (EO experts)
Lille University - Laboratoire d'Optique Atmosphérique (LOA): Prof. Dr. Oleg Dubovik, Drs. Pavel Litvinov (EO experts), Jacques Descloitres (system engineer)
Royal Netherlands Meteorological Institute (KNMI): Drs. Pepijn Veefkind, Gijsbert Tilstra (EO experts, user).
Belgian Institute for Space Aeronomie (BIRA): Drs. Christine Bingen, Sophie Vandebussche (EO experts)
Reference: Dr. Yves Govaerts (EO expert)
Universite Libre de Brussels: Prof. Lieven Clarisse (EO expert)
Ecole Polytechnique (LMD): Dr. Virginie Capelle (EO expert)
Norwegian Meteorological Institute (MetNo): Drs. Michael Schulz, Jan Griesfeller (user, validation expert)
Max-Planck Institute for Meteorology (MPI): Drs. Stefan Kinne, Christoph Brühl (user, validation expert)
Norwegian Institute for Air Reearch (NILU): Dr. Kerstin Stebel (validation expert)
Eidgenössische Technische Hochschule Zürich (ETHZ): Prof. Dr. Ulrike Lohmann, Dr. David Neubaur (user)
Barcelona Supercomputing Center (BSC): Drs. Enza di Tomaso, Sara Basart (user)
London Metropolitan University: Dr. Yong Xue (validation expert)
Freie Universität Berlin (FUB): Prof. Dr. Jürgen Fischer, Dr. Rene Preusker (EO expert)
HYGEOS: Dr. Didier Ramon (EO expert)
Paul Scherrer Institut (PSI): Dr. Paul Zieger (validation expert)

Publications

Following key publications have come out of Aerosol_cci in the last few years

de Leeuw, G., Sogacheva, L., Rodriguez, E., Kourtidis, K., Georgoulias, A. K., Alexandri, G., Amiridis, V., Proestakis, E., Marinou, E., Xue, Y., and van der A, R.: Two decades of satellite observations of AOD over mainland China using ATSR-2, AATSR and MODIS/Terra: data set evaluation and large-scale patterns, Atmos. Chem. Phys., 18, 1573–1592, https://doi.org/10.5194/acp-18-1573-2018, 2018.

Sogacheva, L., de Leeuw, G., Rodriguez, E., Kolmonen, P., Georgoulias, A. K., Alexandri, G., Kourtidis, K., Proestakis, E., Marinou, E., Amiridis, V., Xue, Y., and van der A, R. J.: Spatial and seasonal variations of aerosols over China from two decades of multi-satellite observations – Part 1: ATSR (1995–2011) and MODIS C6.1 (2000–2017), Atmos. Chem. Phys., 18, 11389–11407, https://doi.org/10.5194/acp-18-11389-2018, 2018.

Sogacheva, L., Rodriguez, E., Kolmonen, P., Virtanen, T. H., Saponaro, G., de Leeuw, G., Georgoulias, A. K., Alexandri, G., Kourtidis, K., and van der A, R. J.: Spatial and seasonal variations of aerosols over China from two decades of multi-satellite observations – Part 2: AOD time series for 1995–2017 combined from ATSR ADV and MODIS C6.1 and AOD tendency estimations, Atmos. Chem. Phys., 18, 16631–16652, https://doi.org/10.5194/acp-18-16631-2018, 2018.

Kylling, A., Vandenbussche, S., Capelle, V., Cuesta, J., Klüser, L., Lelli, L., Popp, T., Stebel, K., and Veefkind, P.: Comparison of dust layer heights from active and passive satellite sensors, Atmos. Meas. Tech., 11, 2911-2936, 2018, https://doi.org/10.5194/amt-11-2911-2018, 2018.

C. E. Bulgin, C. J. Merchant, D. Ghent, L. Klüser, T. Popp, C. Poulsen, L. Sogacheva, Quantifying Uncertainty in Satellite-Retrieved Land Surface Temperature from Cloud Detection Errors, Remote Sensing, 10(4), 616; https://doi.org/10.3390/rs10040616, 2018.

J. Christopher Kaiser, Johannes Hendricks, Mattia Righi, Patrick Jöckel, Holger Tost, Konrad Kandler, Bernadett Weinzierl, Daniel Sauer, Katharina Heimerl, Joshua P. Schwarz, Anne E. Perring, and Thomas Popp, Global aerosol modeling with MADE3 (v3.0) in EMAC (based on v2.53): model description and evaluation, Geoscientific Model Development, 12, 541–579, https://doi.org/10.5194/gmd-12-541-2019, 2019.

Sogacheva, L., Popp, T., Sayer, A. M., Dubovik, O., Garay, M. J., Heckel, A., Hsu, N. C., Jethva, H., Kahn, R. A., Kolmonen, P., Kosmale, M., de Leeuw, G., Levy, R. C., Litvinov, P., Lyapustin, A., North, P., Torres, O., and Arola, A.: Merging regional and global aerosol optical depth records from major available satellite products, Atmos. Chem. Phys., 20, 2031–2056, https://doi.org/10.5194/acp-20-2031-2020, 2020.

Sayer, A. M., Govaerts, Y., Kolmonen, P., Lipponen, A., Luffarelli, M., Mielonen, T., Patadia, F., Popp, T., Povey, A. C., Stebel, K., and Witek, M. L.: A review and framework for the evaluation of pixel-level uncertainty estimates in satellite aerosol remote sensing, Atmospheric Measurements and Techniques, 13, 373–404, https://doi.org/10.5194/amt-13-373-2020, 2020.

Popp Thomas, Michaela I. Hegglin, Rainer Hollmann, Fabrice Ardhuin, Annett Bartsch, Ana Bastos, Victoria Bennett, Jacqueline Boutin, Michael Buchwitz, Emilio Chuvieco, Philippe Ciais, Wouter Dorigo, Darren Ghent, Richard Jones, Thomas Lavergne, Christopher Merchant, Benoit Meyssignac, Frank Paul, Shaun Quegan, Tracy Scanlon, Marc Schröder, Stefan Simis, Ulrika Willén, Consistency of satellite climate data records for Earth system monitoring, Bulletin of the American Meteorological Society, 101 E1948–E1971., DOI10.1175/BAMS-D-19-0127.1, 2020

Luffarelli, Marta, Yves Govaerts, and Lucio Franceschini. 2022. “Aerosol Optical Thickness Retrieval in Presence of Cloud: Application to S3A/SLSTR Observations.” Atmosphere 13 (5): 691. https://doi.org/10.3390/atmos13050691

Thomas Popp, Johnathan Mittaz, Systematic propagation of AVHRR AOD uncertainties - a case study to demonstrate the FIDUCEO approach, Remote Sensing, 14, 875, https://doi.org/10.3390/rs14040875, 2022