Search engine for discovering works of Art, research articles, and books related to Art and Culture
Javascript must be enabled to continue!
A comparison between Envisat and ICESat sea ice thickness in the Antarctic
View through CrossRef
Abstract. The crucial role that Antarctic sea ice plays in the global climate system is strongly linked to its thickness. While field observations are too sparse in the Antarctic to determine long-term trends of the Antarctic sea ice thickness (SIT) on a hemispheric scale, satellite radar altimetry data can be applied with a promising prospect. European Space Agency Climate Change Initiative – Sea Ice Project (ESA SICCI) includes sea ice freeboard and sea ice thickness derived from Envisat, covering the entire Antarctic year-round from 2002 to 2012. In this study, the SICCI Envisat SIT in the Antarctic is first compared with a conceptually new ICESat SIT product retrieved from an algorithm employing modified ice density. Both data sets are compared to SIT estimates from upward-looking sonar (ULS) in the Weddell Sea, showing mean differences (MD) and standard deviations (SD) of 1.29 (0.65) m for Envisat-ULS, while we find 1.11 (0.81) m for ICESat-ULS, respectively. The inter-comparisons are conducted for three seasons except winter, based on the ICESat operating periods. According to the results, the differences between Envisat and ICESat SIT reveal significant temporal and spatial variations. More specifically, the smallest seasonal SIT MD (with SD shown in brackets) of 0.00 m (0.39 m) for Envisat-ICESat for the entire Antarctic is found in spring (October–November) while larger MD of 0.52 m (0.68 m) and 0.57 m (0.45 m) exist in summer (February–March) and autumn (May–June), respectively. It is also shown that from autumn to spring, mean Envisat SIT decreases while mean ICESat SIT increases. Our findings suggest that overestimation of Envisat sea ice freeboard, potentially caused by radar backscatter originating from inside the snow layer, primarily accounts for the differences between Envisat and ICESat SIT in summer and autumn, while the uncertainties of snow depth product are not the dominant cause of the differences.To get a better understanding of the characteristics of the Envisat-derived sea ice thickness product, we firstly conduct a comprehensive comparison between Envisat and ICESat-1 sea ice thickness. Their differences reveal significant temporal and spatial variations. Our findings suggest that overestimation of Envisat sea ice freeboard primarily accounts for the differences in summer and autumn, while the uncertainties of snow depth product are not the dominant cause of the differences.
Copernicus GmbH
Title: A comparison between Envisat and ICESat sea ice thickness in the Antarctic
Description:
Abstract.
The crucial role that Antarctic sea ice plays in the global climate system is strongly linked to its thickness.
While field observations are too sparse in the Antarctic to determine long-term trends of the Antarctic sea ice thickness (SIT) on a hemispheric scale, satellite radar altimetry data can be applied with a promising prospect.
European Space Agency Climate Change Initiative – Sea Ice Project (ESA SICCI) includes sea ice freeboard and sea ice thickness derived from Envisat, covering the entire Antarctic year-round from 2002 to 2012.
In this study, the SICCI Envisat SIT in the Antarctic is first compared with a conceptually new ICESat SIT product retrieved from an algorithm employing modified ice density.
Both data sets are compared to SIT estimates from upward-looking sonar (ULS) in the Weddell Sea, showing mean differences (MD) and standard deviations (SD) of 1.
29 (0.
65) m for Envisat-ULS, while we find 1.
11 (0.
81) m for ICESat-ULS, respectively.
The inter-comparisons are conducted for three seasons except winter, based on the ICESat operating periods.
According to the results, the differences between Envisat and ICESat SIT reveal significant temporal and spatial variations.
More specifically, the smallest seasonal SIT MD (with SD shown in brackets) of 0.
00 m (0.
39 m) for Envisat-ICESat for the entire Antarctic is found in spring (October–November) while larger MD of 0.
52 m (0.
68 m) and 0.
57 m (0.
45 m) exist in summer (February–March) and autumn (May–June), respectively.
It is also shown that from autumn to spring, mean Envisat SIT decreases while mean ICESat SIT increases.
Our findings suggest that overestimation of Envisat sea ice freeboard, potentially caused by radar backscatter originating from inside the snow layer, primarily accounts for the differences between Envisat and ICESat SIT in summer and autumn, while the uncertainties of snow depth product are not the dominant cause of the differences.
To get a better understanding of the characteristics of the Envisat-derived sea ice thickness product, we firstly conduct a comprehensive comparison between Envisat and ICESat-1 sea ice thickness.
Their differences reveal significant temporal and spatial variations.
Our findings suggest that overestimation of Envisat sea ice freeboard primarily accounts for the differences in summer and autumn, while the uncertainties of snow depth product are not the dominant cause of the differences.
.
Related Results
A comparison between Envisat and ICESat sea ice thickness in the
Antarctic
A comparison between Envisat and ICESat sea ice thickness in the
Antarctic
Abstract. The crucial role that Antarctic sea ice plays in the global climate system is strongly linked to its thickness. While in situ observations are too sparse in the Antarctic...
Ground ice detection and implications for permafrost geomorphology
Ground ice detection and implications for permafrost geomorphology
Most permafrost contains ground ice, often as pore ice or thin veins or lenses of ice. In certain circumstance, larger bodies of ice can form, such as ice wedges, or massive lenses...
A new HPLC-MS method for fatty acid detection in sea ice
A new HPLC-MS method for fatty acid detection in sea ice
The presence of marine-sourced fatty acids1,2,3, in Antarctic ice cores has been linked to changes in sea ice conditions2,3. It has been proposed that the phytoplankton within and ...
Estimates of wave attenuation from ICESat-2 observations
Estimates of wave attenuation from ICESat-2 observations
Energetic waves originating from the Southern Ocean can propagate great distances into the Antarctic ice pack. Along the way, they can significantly alter the composition of the ic...
The sea ice in Young Sound: Implications for carbon cycling
The sea ice in Young Sound: Implications for carbon cycling
Most of the year, Young Sound is covered by c. 160 cm thick sea ice overlain by a 20-100 cm thick snow cover. During the last 50 years the sea-ice-free period has varied between 63...
Antarctic sea ice types from active and passive microwave remote sensing
Antarctic sea ice types from active and passive microwave remote sensing
Abstract. Polar sea ice is one of the Earth’s climate components that has been significantly affected by the recent trend of global warming. While the sea ice area in the Arctic ha...
Sea ice deformation and thickness in the Western Ross Sea
Sea ice deformation and thickness in the Western Ross Sea
<p>Sea ice cover is arguably the longest and best observed climate variable from space, with over four decades of highly reliable daily records of extent in both hemi...
Modelling the present-day imbalance of the Antarctic Ice Sheet
Modelling the present-day imbalance of the Antarctic Ice Sheet
Recent human-driven climate change has very likely caused more frequent heatwaves, extreme weather events, and rising global sea levels. When it comes to rising sea levels, two pri...