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Details of Award

NERC Reference : NE/H012869/1

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Seismic characterisation of subglacial conditions beneath the margin of the West Greenland Ice Sheet

Grant Award

Principal Investigator:
Professor B Kulessa, Swansea University, School of the Environment and Society
Co-Investigator:
Professor T Murray, Swansea University, College of Science
Co-Investigator:
Professor A Hubbard, UiT Arctic University of Norway (Tromso), UNLISTED
Grant held at:
Swansea University, School of the Environment and Society
Science Area:
Freshwater
Earth
Atmospheric
Overall Classification:
Earth
Science Classification details
ENRIs:
Global Change
Science Topics:
Hydrological Processes
Glacial & Cryospheric Systems
Climate & Climate Change
Abstract:
The response of the Greenland Ice Sheet to a warming climate is of great significance for models of sea-level rise. As such, it receives significant attention from the media, among the general public and in government policy decisions. However, its behaviour is influenced by a number of complex processes, the interactions between which are not well understood. The ice sheet is therefore a focus of major scientific research campaigns, exploring the key influences on its stability and how it will evolve in the future. Recent research has suggested that water is a significant influence on ice sheet stability. Water that is present at the base of the ice sheet acts as a lubricant between the ice and the material beneath it, allowing the ice to move at a faster velocity. For the West Greenland Ice Sheet, a source of basal water is stored in surface meltwater lakes. These form at the start of the summer melt season, in June and July, and typically undergo one or more drainage events throughout July and August. It is believed that the water they contain drains through a network of cracks in the ice, eventually reaching the base of the ice sheet and causing a dynamic response. The drainage of these lakes is rather sudden (in one example, a lake with an area around 6 km2 was drained in under 2 hours) hence a large volume of water can be introduced to the bed of the ice sheet in a short space of time. Certain scientific groups have observed the drainage of a meltwater lake, and have detected increases in local ice dynamics very soon after; this clearly implies that the theory of meltwater reaching the bed of the ice sheet is correct. However, the delivery of meltwater has never been imaged directly; it has only been inferred from responses in other datasets. In this proposal, we intend to detect, delineate and quantify the passage of meltwater at the bed of the ice sheet in seismic geophysical data, which are widely used for this purpose in other areas of the earth sciences and commercial practice. The geophysical techniques we propose have been extensively applied to estimating the fluid content in the subsurface. Water modifies the physical properties of the subsurface to which seismic energy is particularly sensitive. We therefore intend to use geophysics to continually monitor the base of the ice sheet, throughout the melt-and-drainage season in July and August. We anticipate that our seismic data would show the basal water content to increase gradually, as an increasing number of meltwater lakes drain in the vicinity of the survey site. Our specific field site is located amongst a cluster of lakes and moulins (vertical or sub-vertical openings facilitating water drainage into the ice body), and located directly over an area of the ice sheet previously shown to respond to lake drainage events. We are therefore confident that if that response is due to the delivery of meltwater to the bed of the ice sheet, that meltwater will be detectable by our geophysical survey. Our observations will be complemented by a range of results from complementary scientific projects already underway at the site. This includes, e.g., airborne and ground-based radar, passive seismic and GPS assessment or monitoring, and a new catchment-scale model of surface-melt coupled dynamic feedbacks. Meltwater is an important influence on ice dynamics that, with continued global warming, is likely to become more significant in the future. Understanding that influence is therefore crucial for predicting how the Greenland Ice Sheet will respond to climate change, and the observations made during this study will undoubtedly contribute to our knowledge of ice dynamics.
Period of Award:
1 Jun 2010 - 31 May 2011
Value:
£41,703
(FY details)
Authorised funds only
NERC Reference:
NE/H012869/1
Grant Stage:
Awaiting Completion
Scheme:
Small Grants (FEC)
Grant Status:
Closed
Programme:
Small Grants

This grant award has a total value of £41,703  

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FDAB - Financial Details (Award breakdown by headings)

DI - Other CostsIndirect - Indirect CostsDA - InvestigatorsDA - Estate CostsDA - Other Directly AllocatedDI - T&S
£8,476£6,120£12,855£2,054£322£11,876

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