by Mauri Pelto, From a Glacier's Perspective, August 27, 2012
In an article Dan Bailey and I published at Skeptical Science, we observed that in northern Greenland high velocities extend far inland only on Zachariae and Petermann Glacier tapping into the midst of the ice sheet in northern Greenland. Further, it is the Zachariae Isstrøm (ZIS) that is likely the only of this group that would be comparable to a bank that is too big to fail as its increased velocity band extends well into the ice sheet. ZIS is one of the three main outlets of the northeast Greenland Ice Stream, Storstrommen and Nioghalvfjerdsfjorden (79N) are the other two.
The extent of the high velocity zone is evident in the first image below from the exceptionally detailed work of Joughin et al. (2010), and Joughin et al. (2001). The area of high velocity versus the surrounding ice at over 100 m/year extends 350 km upglacier from the ZIS terminus. The velocity then increased from 100 to 400+ m/year from 200-100 km from the ice front. At the grounding line, the velocity is 1100 m/year (Rignot et al, 2001). The velocity remains high to the ZIS icefront. The width of the ice stream identified by the zone of higher flow is 40 km wide 350 km above the terminus and remains at least 30 km wide all the way to the terminus region. The velocity is lower than on Jakobshavns, but the ice stream is also much wider.
A view of the basal topography from Joughin et al. (2001) indicates that the acceleration occurs in the same area as the bed depth drops significantly below sea level 200 km from the ice front. The base of the glacier is 300-700 meters below sea level all the way to the ice front. The thickness at the grounding line is noted as 550-600 meters by Rignot et al. (2001). The result is an ice flux at the grounding line of ZIS of some 11 cubic kilometers per year, this is much less than the 40+ cubic kilometers from Jakobshavn Isbrae and similar to the 12 cubic kilometers from Petermann Glacier. The red arrows in both images indicates the area of fast ice, discussed below and the yellow arrow the location of the new 2012 ice front.
This post examines recent changes in ZIS updating the work of Box and Decker (2011). They noted an average decadal rate of loss of 14 square kilometers/year and the evolving terminus position in the first image below from Jason Box at Meltfactor.org. Box and Decker (2011) also noted a potential advance in 2006-2007, that we will further explore here.
This post examines recent changes in ZIS updating the work of Box and Decker (2011). They noted an average decadal rate of loss of 14 square kilometers/year and the evolving terminus position in the first image below from Jason Box at Meltfactor.org. Box and Decker (2011) also noted a potential advance in 2006-2007, that we will further explore here.
The reduced sea ice in the region has exposed the ZIS terminus to increased open water in what was typically a region that was dominated by persistent sea ice. The enhanced surface melting is also a concern. In 2012 ZIS has experienced an additional retreat that has separated the main glacier from a melange of glacier ice and fast sea ice on the northeast side of the terminus. The changes have been an ongoing watch by several of the participants at the Arctic Sea Ice blog, which has developed into a wonderful community for daily detailed sea ice observations. Espen Olesen and I have discussed the split that occurred this August which warrants pointing out. Here we examine Landsat imagery from 2006, 2008, 2009 and 2010 and MODIS imagery from 2011 and Aug. 19 2012 to depict the changes. The last image is a July 30, 2012, Landsat with the purple terminus line indicated. The images are shown below with the fast ice zone (FI) noted in 2006 and the MODIS images from 2011 and 2012. The new 2012 terminus that has retreated to the corner of is indicated by a yellow arrow. The actual terminus in the Landsat images is indicated by purple dots, but based on the melange that exists on the east side and fast ice on the north side this is not a clear cut distinction. The fast ice is distorted in a convex pattern by the impinging ice front in the Landsat images. The new terminus is at the southeast corner of Lambert land and extends directly southwest to Heretugen Orleans Land.
The retreat follows the calving events on Petermann and Steesnby Glacier. Here there is no single large iceberg to observe. The retreat from 2010 to 2012 is approximately 10 km, the loss of area is particularly hard to accurately determine, today I estimate it is 70 km2, and will look to better derive this estimate from new imagery from Geoeye and other satellites in the coming days and would welcome other such area loss analyses for the 2006-2012 period. The potential advance from 2006-2007 is simply not observed here.
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