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Greenland meltwater storage in firn limited by near-surface ice formation

Nature Climate Change volume 6pages 390–393 (2016)Cite this article

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Abstract

Approximately half of Greenland’s current annual mass loss is attributed to runoff from surface melt1. At higher elevations, however, melt does not necessarily equal runoff, because meltwater can refreeze in the porous near-surface snow and firn2. Two recent studies suggest that all3 or most3,4 of Greenland’s firn pore space is available for meltwater storage, making the firn an important buffer against contribution to sea level rise for decades to come3. Here, we employ in situ observations and historical legacy data to demonstrate that surface runoff begins to dominate over meltwater storage well before firn pore space has been completely filled. Our observations frame the recent exceptional melt summers in 2010 and 2012 (refs 5,6), revealing significant changes in firn structure at different elevations caused by successive intensive melt events. In the upper regions (more than 1,900 m above sea level), firn has undergone substantial densification, while at lower elevations, where melt is most abundant, porous firn has lost most of its capability to retain meltwater. Here, the formation of near-surface ice layers renders deep pore space difficult to access, forcing meltwater to enter an efficient7 surface discharge system and intensifying ice sheet mass loss earlier than previously suggested3.

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Figure 1: Map illustrating the firn core sites and main radar transect.
Figure 2: Stratigraphy of the nine major firn cores drilled in late April to mid May 2013.
Figure 3: Changes in firn density from 1997 or 1998 (ref. 16) to 2013 or 2015.

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Acknowledgements

This work is supported by the US National Aeronautics and Space Administration (NASA) Grant no. NNX10AR76G, ‘Comprehensive Assessment of Ice Sheet Contributions to Sea Level Based on Integrated Remote Sensing Observations’, by the Greenland Analogue Project (GAP), funded by Svensk Kärnbränslehantering AB, Sweden, Posiva Oy, Finland, and NWMO, Canada, the Refreeze Project funded by GEUS, the RETAIN project, funded by the Danish Council for Independent research (Grant no. 4002-00234) and the Programme for Monitoring of the Greenland Ice Sheet (PROMICE), funded by The Danish Energy Agency DANCEA programme. Collection and analyses of the legacy cores was supported by NASA’s PARCA Program. The K-transect programme has been funded by Utrecht University, the Netherlands Polar Program of NWO/ALW and a Spinoza grant. This publication is contribution number 62 of the Nordic Centre of Excellence SVALI, ‘Stability and Variations of Arctic Land Ice’, funded by the Nordic Top-level Research Initiative (TRI). The authors acknowledge field assistance by K. Alley, A. Crawford, S. Doyle, M. Eijkelboom, S. Grigsby, D. Hill, A. Heilig, A. Hubbard, K. Lindbäck, R. Petterson and M. Stevens as well as logistical contributions from W. Abdalati, R. Bauer, A. Hubbard and T. Scambos. Satellite imagery in Supplementary Fig. 1 is subject to copyright by European Space Imaging/DigitalGlobe.

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  1. Horst Machguth

    Present address: Present address: Department of Geography, University of Zurich, 8057 Zurich, Switzerland.,

Authors and Affiliations

  1. Geological Survey of Denmark and Greenland GEUS, 1350 København K, Denmark

    Horst Machguth, Dirk van As, Jason E. Box, Charalampos Charalampidis, William Colgan & Robert S. Fausto

  2. Arctic Technology Centre ARTEK, Technical University of Denmark, 2800 Kgs. Lyngby, Denmark

    Horst Machguth

  3. Cooperative Institute for Research in Environmental Sciences (CIRES), University of Colorado at Boulder, Boulder, Colorado 80309, USA

    Mike MacFerrin

  4. Department of Earth Sciences, Uppsala University, 752 36 Uppsala, Sweden

    Charalampos Charalampidis

  5. Department of Earth and Space Science and Engineering, York University, Toronto, Ontario M3J 1P3, Canada

    William Colgan

  6. Centre for Isotope Research (CIO), Energy and Sustainability Research Institute Groningen (ESRIG), University of Groningen, 9747AG Groningen, The Netherlands

    Harro A. J. Meijer

  7. Byrd Polar and Climate Research Center and Department of Geography, The Ohio State University, Columbus, Ohio 43210, USA

    Ellen Mosley-Thompson

  8. Institute for Marine and Atmospheric Research Utrecht (IMAU), University of Utrecht, 3584CC Utrecht, The Netherlands

    Roderik S. W. van de Wal

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Contributions

H.M. conceived the study; M.M., D.v.A. and H.M. collaboratively designed and planned the field campaigns in which M.M., H.M., D.v.A., C.C. and W.C. participated; H.M., M.M., D.v.A., J.E.B., C.C., W.C., R.S.F. and E.M.-T. performed the data analysis; E.M.-T., R.S.W.v.d.W. and H.A.J.M. prepared and provided additional data. H.M. and M.M. wrote the manuscript; all authors continuously discussed the results and developed the analysis further.

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Correspondence to Horst Machguth.

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Machguth, H., MacFerrin, M., van As, D. et al. Greenland meltwater storage in firn limited by near-surface ice formation. Nature Clim Change 6, 390–393 (2016). https://doi.org/10.1038/nclimate2899

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