ESA - GOCE Mission logo.
26 September 2014
Although not designed to map changes in Earth’s gravity over time, ESA’s extraordinary satellite has shown that the ice lost from West Antarctica over the last few years has left its signature.
More than doubling its planned life in orbit, GOCE spent four years measuring Earth’s gravity in unprecedented detail.
GOCE senses changing gravity
Scientists are now armed with the most accurate gravity model ever produced. This is leading to a much better understanding of many facets of our planet – from the boundary between Earth’s crust and upper mantle to the density of the upper atmosphere.
The strength of gravity at Earth’s surface varies subtly from place to place owing to factors such as the planet’s rotation and the position of mountains and ocean trenches.
Changes in the mass of large ice sheets can also cause small local variations in gravity.
Ice loss dips gravity
Recently, the high-resolution measurements from GOCE over Antarctica between November 2009 and June 2012 have been analysed by scientists from the German Geodetic Research Institute, Delft University of Technology in the Netherlands, the Jet Propulsion Lab in USA and the Technical University of Munich in Germany.
Remarkably, they found that the decrease in the mass of ice during this period was mirrored in GOCE’s measurements, even though the mission was not designed to detect changes over time.
Using gravity data to assess changes in ice mass is not new. The NASA–German Grace satellite, which was designed to measure change, has been providing this information for over 10 years.
However, measurements from Grace are much coarser than those of GOCE, so they cannot be used to look at features such as Antarctica’s smaller ‘catchment basins’.
GOCE geoid
For scientific purposes, the Antarctic ice sheet is often divided into catchment basins so that comparative measurements can be taken to work out how the ice in each basin is changing and discharging ice to the oceans. Some basins are much bigger than others.
By combining GOCE’s high-resolution measurements with information from Grace, scientists can now look at changes in ice mass in small glacial systems – offering even greater insight into the dynamics of Antarctica’s different basins.
They have found that that the loss of ice from West Antarctica between 2009 and 2012 caused a dip in the gravity field over the region.
Ice change from CryoSat
In addition, GOCE data could be used to help validate satellite altimetry measurements for an even clearer understanding of ice-sheet and sea-level change.
ESA’s CryoSat satellite, which carries a radar altimeter, has recently shown that since 2009 the rate at which ice is been lost from the West Antarctic Ice Sheet every year has increased by a factor of three.
And, between 2011 and 2014, Antarctica as a whole has been shrinking in volume by 125 cubic kilometres a year.
Johannes Bouman from the German Geodetic Research Institute said, “We are now working in an interdisciplinary team to extend the analysis of GOCE’s data to all of Antarctica.
“This will help us gain further comparison with results from CryoSat for an even more reliable picture of actual changes in ice mass.”
This new research into GOCE’s gravity data revealing ice loss over time is being carried out through ESA’s Earth Observation Support to Science Element.
More information:
STSE ‘GOCE+ Time-Variations’ project:
http://due.esrin.esa.int/stse/projects/stse_project.php?id=135
Geophysical Research Letters:
Bouman et al (2013) Antarctic outlet glacier mass change resolved at basin scale from satellite gravity gradiometry: http://onlinelibrary.wiley.com/doi/10.1002/2014GL060637/abstract
Related links:
DGFI: http://www.dgfi.badw.de/
TU Delft Faculty of Aerospace Engineering: http://www.lr.tudelft.nl/en/
Related missions:
GRACE: http://www.nasa.gov/mission_pages/Grace/
CryoSat: http://www.esa.int/Our_Activities/Observing_the_Earth/CryoSat
Access GOCE data: http://earth.esa.int/GOCE/
Images, Video, Text, Credits: ESA/DGFI/Planetary Visions/HPF/DLR/Helm et al., The Cryosphere, 2014.
Greetings, Orbiter.ch
