Validation of airborne and satellite altimetry data by Arctic Truck citizen science
The elevation of ice sheets changes due to climate change, and satellite altimetry is the preferred tool for measuring ice sheet-wide height changes. In situ validation is needed to ensure the quality of the observed elevation changes, but the cost often limits the amount of in situ data which can b...
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Geological Survey of Denmark and Greenland (GEUS)
2021
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ftjgeusbullet:oai:geusjournals.org:article/5369 2023-05-15T15:17:40+02:00 Validation of airborne and satellite altimetry data by Arctic Truck citizen science Stokholm, Andreas Hvidegaard, Sine M. Forsberg, Rene Simonsen, Sebastian B. 2021-05-28 application/pdf text/html text/xml application/epub+zip https://geusbulletin.org/index.php/geusb/article/view/5369 https://doi.org/10.34194/geusb.v47.5369 eng eng Geological Survey of Denmark and Greenland (GEUS) https://geusbulletin.org/index.php/geusb/article/view/5369/14168 https://geusbulletin.org/index.php/geusb/article/view/5369/14171 https://geusbulletin.org/index.php/geusb/article/view/5369/14170 https://geusbulletin.org/index.php/geusb/article/view/5369/14169 https://geusbulletin.org/index.php/geusb/article/view/5369 doi:10.34194/geusb.v47.5369 Copyright (c) 2021 Andreas Stokholm, Sine M. Hvidegaard, Rene Forsberg, Sebastian B. Simonsen https://creativecommons.org/licenses/by/4.0 CC-BY GEUS Bulletin; Vol. 47 (2021): Annual Volume 2021 2597-2154 2597-2162 Satellite Validation Altimetry CryoSat-2 Operation IceBridge Citizen science info:eu-repo/semantics/article info:eu-repo/semantics/publishedVersion Peer-reviewed Article. 2021 ftjgeusbullet https://doi.org/10.34194/geusb.v47.5369 2022-03-15T17:22:28Z The elevation of ice sheets changes due to climate change, and satellite altimetry is the preferred tool for measuring ice sheet-wide height changes. In situ validation is needed to ensure the quality of the observed elevation changes, but the cost often limits the amount of in situ data which can be collected. As more tourists are accessing the ice sheets, citizen science might provide in situ data in an environmentally friendly and cost-efficient way. Here, we investigate the opportunistic kinematic global positioning system (GPS) profiles across the Greenland ice sheet, collected by the American-Icelandic expedition on the Greenlandic icecap 2018. The collected GPS data are in good agreement with the widely used NASA’s Operation IceBridge Airborne LiDAR data measured within ± 10 days, with an average difference of 10.7 cm ± 11.7 cm. The main difference is attributed to changes in the compaction of the snow while driving and changes in the tires’ pressure. The kinematic GPS data are then compared with data from the European Space Agency’s CryoSat-2 mission. Here, an average bias of 92.3 cm ± 65.7 cm in the two records is observed between the spring CryoSat-2 and the truck GPS data obtained largely in the dry-snow zone. This suggests that the surface penetration of Ku-band radar on the Greenland ice sheet and the observed magnitude are consistent with the literature. Finally, we compared the 2018 GPS data to a profile obtained in 2005 near Kangerlussuaq, West Greenland. Here, the records show an average ice-elevation decrease of 9 m, with peaks at 26 m. These results show that the citizen science kinematic GPS data can provide high-resolution data necessary for the validation of satellite altimetry, with the added benefit of potential direct sampling properties of the surface and firn. Linking up with citizen-science expeditions is a beneficial way of providing cost-effective satellite validations and may also have a societal impact by involving more people in the climate monitoring of ice sheets. Article in Journal/Newspaper Arctic Climate change Greenland greenlandic Ice Sheet Kangerlussuaq GEUS Bulletin (Geological Survey of Denmark and Greenland) Arctic Greenland Kangerlussuaq ENVELOPE(-55.633,-55.633,72.633,72.633) GEUS Bulletin 47 |
institution |
Open Polar |
collection |
GEUS Bulletin (Geological Survey of Denmark and Greenland) |
op_collection_id |
ftjgeusbullet |
language |
English |
topic |
Satellite Validation Altimetry CryoSat-2 Operation IceBridge Citizen science |
spellingShingle |
Satellite Validation Altimetry CryoSat-2 Operation IceBridge Citizen science Stokholm, Andreas Hvidegaard, Sine M. Forsberg, Rene Simonsen, Sebastian B. Validation of airborne and satellite altimetry data by Arctic Truck citizen science |
topic_facet |
Satellite Validation Altimetry CryoSat-2 Operation IceBridge Citizen science |
description |
The elevation of ice sheets changes due to climate change, and satellite altimetry is the preferred tool for measuring ice sheet-wide height changes. In situ validation is needed to ensure the quality of the observed elevation changes, but the cost often limits the amount of in situ data which can be collected. As more tourists are accessing the ice sheets, citizen science might provide in situ data in an environmentally friendly and cost-efficient way. Here, we investigate the opportunistic kinematic global positioning system (GPS) profiles across the Greenland ice sheet, collected by the American-Icelandic expedition on the Greenlandic icecap 2018. The collected GPS data are in good agreement with the widely used NASA’s Operation IceBridge Airborne LiDAR data measured within ± 10 days, with an average difference of 10.7 cm ± 11.7 cm. The main difference is attributed to changes in the compaction of the snow while driving and changes in the tires’ pressure. The kinematic GPS data are then compared with data from the European Space Agency’s CryoSat-2 mission. Here, an average bias of 92.3 cm ± 65.7 cm in the two records is observed between the spring CryoSat-2 and the truck GPS data obtained largely in the dry-snow zone. This suggests that the surface penetration of Ku-band radar on the Greenland ice sheet and the observed magnitude are consistent with the literature. Finally, we compared the 2018 GPS data to a profile obtained in 2005 near Kangerlussuaq, West Greenland. Here, the records show an average ice-elevation decrease of 9 m, with peaks at 26 m. These results show that the citizen science kinematic GPS data can provide high-resolution data necessary for the validation of satellite altimetry, with the added benefit of potential direct sampling properties of the surface and firn. Linking up with citizen-science expeditions is a beneficial way of providing cost-effective satellite validations and may also have a societal impact by involving more people in the climate monitoring of ice sheets. |
format |
Article in Journal/Newspaper |
author |
Stokholm, Andreas Hvidegaard, Sine M. Forsberg, Rene Simonsen, Sebastian B. |
author_facet |
Stokholm, Andreas Hvidegaard, Sine M. Forsberg, Rene Simonsen, Sebastian B. |
author_sort |
Stokholm, Andreas |
title |
Validation of airborne and satellite altimetry data by Arctic Truck citizen science |
title_short |
Validation of airborne and satellite altimetry data by Arctic Truck citizen science |
title_full |
Validation of airborne and satellite altimetry data by Arctic Truck citizen science |
title_fullStr |
Validation of airborne and satellite altimetry data by Arctic Truck citizen science |
title_full_unstemmed |
Validation of airborne and satellite altimetry data by Arctic Truck citizen science |
title_sort |
validation of airborne and satellite altimetry data by arctic truck citizen science |
publisher |
Geological Survey of Denmark and Greenland (GEUS) |
publishDate |
2021 |
url |
https://geusbulletin.org/index.php/geusb/article/view/5369 https://doi.org/10.34194/geusb.v47.5369 |
long_lat |
ENVELOPE(-55.633,-55.633,72.633,72.633) |
geographic |
Arctic Greenland Kangerlussuaq |
geographic_facet |
Arctic Greenland Kangerlussuaq |
genre |
Arctic Climate change Greenland greenlandic Ice Sheet Kangerlussuaq |
genre_facet |
Arctic Climate change Greenland greenlandic Ice Sheet Kangerlussuaq |
op_source |
GEUS Bulletin; Vol. 47 (2021): Annual Volume 2021 2597-2154 2597-2162 |
op_relation |
https://geusbulletin.org/index.php/geusb/article/view/5369/14168 https://geusbulletin.org/index.php/geusb/article/view/5369/14171 https://geusbulletin.org/index.php/geusb/article/view/5369/14170 https://geusbulletin.org/index.php/geusb/article/view/5369/14169 https://geusbulletin.org/index.php/geusb/article/view/5369 doi:10.34194/geusb.v47.5369 |
op_rights |
Copyright (c) 2021 Andreas Stokholm, Sine M. Hvidegaard, Rene Forsberg, Sebastian B. Simonsen https://creativecommons.org/licenses/by/4.0 |
op_rightsnorm |
CC-BY |
op_doi |
https://doi.org/10.34194/geusb.v47.5369 |
container_title |
GEUS Bulletin |
container_volume |
47 |
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1766347915453792256 |