The 1988–2003 Greenland ice sheet melt extent using passive microwave satellite data and a regional climate model

Measurements from ETH-Camp and JAR1 AWS (West Greenland) as well as coupled atmosphere-snow regional climate simulations have highlighted flaws in the cross-polarized gradient ratio (XPGR) technique used to identify melt from passive microwave satellite data. It was found that dense clouds (causing notably rainfall) on the ice sheet severely perturb the XPGR melt signal. Therefore, the original XPGR melt detection algorithm has been adapted to better incorporate atmospheric variability over the ice sheet and an updated melt trend for the 1988–2003 period has been calculated. Compared to the original algorithm, the melt zone area increase is eight times higher (from 0.2 to 1.7% year−1). The increase is higher with the improved XPGR technique because rainfall also increased during this period. It is correlated to higher atmospheric temperatures. Finally, the model shows that the total ice sheet runoff is directly proportional to the melt extent surface detected by satellites. These results are important for the understanding of the effect of Greenland melting on the stability of the thermohaline circulation.

[1]  E. Brun,et al.  Impact Of Snow Drift On The Antarctic Ice Sheet Surface Mass Balance: Possible Sensitivity To Snow-Surface Properties , 2001 .

[2]  H. Gallée,et al.  Development of a Three-Dimensional Meso-γ Primitive Equation Model: Katabatic Winds Simulation in the Area of Terra Nova Bay, Antarctica , 1994 .

[3]  Konrad Steffen,et al.  Snowmelt on the Greenland Ice Sheet as Derived from Passive Microwave Satellite Data , 1997 .

[4]  Konrad Steffen,et al.  Greenland Ice Sheet melt extent: 1979–1999 , 2001 .

[5]  X. Fettweis,et al.  Evaluation of a high-resolution regional climate simulation over Greenland , 2005 .

[6]  X. Fettweis,et al.  Greenland surface mass balance simulated by a regional climate model and comparison with satellite-derived data in 1990–1991 , 2005 .

[7]  T. Mote Estimation of runoff rates, mass balance, and elevation changes on the Greenland ice sheet from passive microwave observations , 2003 .

[8]  Son V. Nghiem,et al.  The melt anomaly of 2002 on the Greenland Ice Sheet from active and passive microwave satellite observations , 2004 .

[9]  Konrad Steffen,et al.  Surface Melt-Induced Acceleration of Greenland Ice-Sheet Flow , 2002, Science.

[10]  W. Krabill,et al.  Greenland Ice Sheet: High-Elevation Balance and Peripheral Thinning. , 2000, Science.

[11]  The capillary effects on water percolation in homogeneous snow , 1974 .

[12]  Eric Rignot,et al.  Mass Balance of Polar Ice Sheets , 2002, Science.

[13]  J. Gregory,et al.  Climatic Impact of a Greenland Deglaciation and Its Possible Irreversibility , 2003 .

[14]  Koen De Ridder,et al.  Land Surface-Induced Regional Climate Change in Southern Israel , 1998 .

[15]  J. Box Survey of Greenland instrumental temperature records: 1873–2001 , 2002 .

[16]  Konrad Steffen,et al.  Surface climatology of the Greenland Ice Sheet: Greenland Climate Network 1995–1999 , 2001 .

[17]  X. Fettweis,et al.  Greenland surface mass balance Greenland surface mass balance simulated by a regional climate model and simulated by a regional climate model and comparison with satellite derived data in 1990-1991. comparison with satellite derived data in 1990-1991. , 2007 .

[18]  Jason E. Box,et al.  Greenland ice sheet surface mass balance 1991–2000: Application of Polar MM5 mesoscale model and in situ data , 2004 .

[19]  C. Deehr,et al.  Ground‐based optical observations of hydrogen emission in the auroral substorm , 2001 .

[20]  Quirin Schiermeier,et al.  Greenland's climate: A rising tide , 2004, Nature.

[21]  F. Lefebre,et al.  Modeling of snow and ice melt at ETH Camp (West Greenland): A study of surface albedo , 2003 .

[22]  Michel Fily,et al.  Variability and trends of the summer melt period of Antarctic ice margins since 1980 from microwave sensors , 2003 .