TROPOMI/S5P Total Column Water Vapor validation against AERONET ground-based measurements

Water vapor plays an important role in the greenhouse effect, rendering it an atmospheric constituent that requires continuous and global monitoring by different types of remote sensing instruments. The TROPOspheric Monitoring Instrument Sentinel-5 Precursor (TROPOMI/S5P) Total Column Water Vapor (T...

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Published in:Atmospheric Measurement Techniques
Main Authors: Garane, Katerina, Chan, Ka Lok, Koukouli, Maria-Elissavet, Loyola, Diego, Balis, Dimitris
Format: Article in Journal/Newspaper
Language:English
Published: Copernicus Publications 2023
Subjects:
Atmosphärenprozessoren
Aerosol Robotic Network
Online Access:https://elib.dlr.de/193030/
https://doi.org/10.5194/amt-16-57-2023
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author Garane, Katerina
Chan, Ka Lok
Koukouli, Maria-Elissavet
Loyola, Diego
Balis, Dimitris
author_facet Garane, Katerina
Chan, Ka Lok
Koukouli, Maria-Elissavet
Loyola, Diego
Balis, Dimitris
author_sort Garane, Katerina
collection Unknown
container_issue 1
container_start_page 57
container_title Atmospheric Measurement Techniques
container_volume 16
description Water vapor plays an important role in the greenhouse effect, rendering it an atmospheric constituent that requires continuous and global monitoring by different types of remote sensing instruments. The TROPOspheric Monitoring Instrument Sentinel-5 Precursor (TROPOMI/S5P) Total Column Water Vapor (TCWV) is a new product retrieved from the visible blue spectral range (435–455 nm), using an algorithm that was originally developed for the GOME-2/MetOp sensors. For the purposes of this work, 2.5 years of continuous satellite observations at high spatial resolution are validated against co-located (in space and in time) precipitable water Level 2.0 (quality-assured) ground-based measurements from the NASA AERONET (AErosol RObotic NETwork). The network uses Cimel Sun photometers located at approximately 1300 stations globally to monitor precipitable water among other products. Based on data availability, 369 of the stations were used in this study. The two datasets, satellite- and ground-based, were co-located, and the relative differences of the comparisons were calculated and statistically analyzed. The Pearson correlation coefficient of the two products is found to be 0.91, and the mean bias of the overall relative percentage differences is of the order of −2.7 %. For the Northern Hemisphere midlatitudes (30–60∘ N), where the density of the ground-based stations is high, the mean relative bias was found to be −1.8 %, while in the tropics (±15∘) the TROPOMI TCWV product has a relative dry bias of up to −10 %. The effect of various algorithm and geophysical parameters, such as air mass factor, solar zenith angle, clouds and albedo, is also presented and discussed. It was found that the cloud properties affect the validation results, leading the TCWV to a dry bias of −20 % for low cloud heights (cloud top pressure (CTP) >800 hPa). Moreover, cloud albedo introduces a wet bias of 15 % when it is below 0.3 and a dry bias up to −25 % when the clouds are more reflective. Overall, the TROPOMI/S5P TCWV product, on a ...
format Article in Journal/Newspaper
genre Aerosol Robotic Network
genre_facet Aerosol Robotic Network
id ftdlr:oai:elib.dlr.de:193030
institution Open Polar
language English
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op_container_end_page 74
op_doi https://doi.org/10.5194/amt-16-57-2023
op_relation https://elib.dlr.de/193030/1/amt-16-57-2023.pdf
Garane, Katerina und Chan, Ka Lok und Koukouli, Maria-Elissavet und Loyola, Diego und Balis, Dimitris (2023) TROPOMI/S5P Total Column Water Vapor validation against AERONET ground-based measurements. Atmospheric Measurement Techniques (AMT), 16, Seiten 57-74. Copernicus Publications. doi:10.5194/amt-16-57-2023 <https://doi.org/10.5194/amt-16-57-2023>. ISSN 1867-1381.
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spelling ftdlr:oai:elib.dlr.de:193030 2025-06-15T14:05:43+00:00 TROPOMI/S5P Total Column Water Vapor validation against AERONET ground-based measurements Garane, Katerina Chan, Ka Lok Koukouli, Maria-Elissavet Loyola, Diego Balis, Dimitris 2023-01-06 application/pdf https://elib.dlr.de/193030/ https://doi.org/10.5194/amt-16-57-2023 en eng Copernicus Publications https://elib.dlr.de/193030/1/amt-16-57-2023.pdf Garane, Katerina und Chan, Ka Lok und Koukouli, Maria-Elissavet und Loyola, Diego und Balis, Dimitris (2023) TROPOMI/S5P Total Column Water Vapor validation against AERONET ground-based measurements. Atmospheric Measurement Techniques (AMT), 16, Seiten 57-74. Copernicus Publications. doi:10.5194/amt-16-57-2023 <https://doi.org/10.5194/amt-16-57-2023>. ISSN 1867-1381. cc_by Atmosphärenprozessoren Zeitschriftenbeitrag PeerReviewed 2023 ftdlr https://doi.org/10.5194/amt-16-57-2023 2025-06-04T04:58:08Z Water vapor plays an important role in the greenhouse effect, rendering it an atmospheric constituent that requires continuous and global monitoring by different types of remote sensing instruments. The TROPOspheric Monitoring Instrument Sentinel-5 Precursor (TROPOMI/S5P) Total Column Water Vapor (TCWV) is a new product retrieved from the visible blue spectral range (435–455 nm), using an algorithm that was originally developed for the GOME-2/MetOp sensors. For the purposes of this work, 2.5 years of continuous satellite observations at high spatial resolution are validated against co-located (in space and in time) precipitable water Level 2.0 (quality-assured) ground-based measurements from the NASA AERONET (AErosol RObotic NETwork). The network uses Cimel Sun photometers located at approximately 1300 stations globally to monitor precipitable water among other products. Based on data availability, 369 of the stations were used in this study. The two datasets, satellite- and ground-based, were co-located, and the relative differences of the comparisons were calculated and statistically analyzed. The Pearson correlation coefficient of the two products is found to be 0.91, and the mean bias of the overall relative percentage differences is of the order of −2.7 %. For the Northern Hemisphere midlatitudes (30–60∘ N), where the density of the ground-based stations is high, the mean relative bias was found to be −1.8 %, while in the tropics (±15∘) the TROPOMI TCWV product has a relative dry bias of up to −10 %. The effect of various algorithm and geophysical parameters, such as air mass factor, solar zenith angle, clouds and albedo, is also presented and discussed. It was found that the cloud properties affect the validation results, leading the TCWV to a dry bias of −20 % for low cloud heights (cloud top pressure (CTP) >800 hPa). Moreover, cloud albedo introduces a wet bias of 15 % when it is below 0.3 and a dry bias up to −25 % when the clouds are more reflective. Overall, the TROPOMI/S5P TCWV product, on a ... Article in Journal/Newspaper Aerosol Robotic Network Unknown Atmospheric Measurement Techniques 16 1 57 74
spellingShingle Atmosphärenprozessoren
Garane, Katerina
Chan, Ka Lok
Koukouli, Maria-Elissavet
Loyola, Diego
Balis, Dimitris
TROPOMI/S5P Total Column Water Vapor validation against AERONET ground-based measurements
title TROPOMI/S5P Total Column Water Vapor validation against AERONET ground-based measurements
title_full TROPOMI/S5P Total Column Water Vapor validation against AERONET ground-based measurements
title_fullStr TROPOMI/S5P Total Column Water Vapor validation against AERONET ground-based measurements
title_full_unstemmed TROPOMI/S5P Total Column Water Vapor validation against AERONET ground-based measurements
title_short TROPOMI/S5P Total Column Water Vapor validation against AERONET ground-based measurements
title_sort tropomi/s5p total column water vapor validation against aeronet ground-based measurements
topic Atmosphärenprozessoren
topic_facet Atmosphärenprozessoren
url https://elib.dlr.de/193030/
https://doi.org/10.5194/amt-16-57-2023

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