Your search keyword '"Langen PL"' showing total 2 results

1. Rapid expansion of Greenland's low-permeability ice slabs.

Author

MacFerrin M, Machguth H, As DV, Charalampidis C, Stevens CM, Heilig A, Vandecrux B, Langen PL, Mottram R, Fettweis X, Broeke MRVD, Pfeffer WT, Moussavi MS, and Abdalati W

Subjects

Freezing, Global Warming, Greenland, Ice Cover, Models, Theoretical

Abstract

In recent decades, meltwater runoff has accelerated to become the dominant mechanism for mass loss in the Greenland ice sheet 1-3 . In Greenland's high-elevation interior, porous snow and firn accumulate; these can absorb surface meltwater and inhibit runoff 4 , but this buffering effect is limited if enough water refreezes near the surface to restrict percolation 5,6 . However, the influence of refreezing on runoff from Greenland remains largely unquantified. Here we use firn cores, radar observations and regional climate models to show that recent increases in meltwater have resulted in the formation of metres-thick, low-permeability 'ice slabs' that have expanded the Greenland ice sheet's total runoff area by 26 ± 3 per cent since 2001. Although runoff from the top of ice slabs has added less than one millimetre to global sea-level rise so far, this contribution will grow substantially as ice slabs expand inland in a warming climate. Runoff over ice slabs is set to contribute 7 to 33 millimetres and 17 to 74 millimetres to global sea-level rise by 2100 under moderate- and high-emissions scenarios, respectively-approximately double the estimated runoff from Greenland's high-elevation interior, as predicted by surface mass balance models without ice slabs. Ice slabs will have an important role in enhancing surface meltwater feedback processes, fundamentally altering the ice sheet's present and future hydrology.

Published

2019

2. Towards quantifying the glacial runoff signal in the freshwater input to Tyrolerfjord-Young Sound, NE Greenland.

Author

Citterio M, Sejr MK, Langen PL, Mottram RH, Abermann J, Hillerup Larsen S, Skov K, and Lund M

Subjects

Arctic Regions, Ecological Parameter Monitoring, Greenland, Snow, Temperature, Weather, Climate Change, Fresh Water, Ice Cover, Models, Theoretical

Abstract

Terrestrial freshwater runoff strongly influences physical and biogeochemical processes at the fjord scale and can have global impacts when considered at the Greenland scale. We investigate the performance of the HIRHAM5 regional climate model over the catchments delivering freshwater to Tyrolerfjord and Young Sound by comparing to the unique Greenland Ecological Monitoring database of in situ observations from this region. Based on these findings, we estimate and discuss the fraction of runoff originating from glacierized and non-glacierized land delivered at the daily scale between 1996 and 2008. We find that glaciers contributed on average 50-80% of annual terrestrial runoff when considering different sections of Tyrolerfjord-Young Sound, but snowpack depletion on land and consequently runoff happens about one month earlier in the model than observed in the field. The temporal shift in the model is a likely explanation why summer surface salinity in the inner fjord did not correlate to modelled runoff.

Published

2017