Your search keyword '"Ashmore, David W."' showing total 4 results

1. Crevasse density, orientation, and temporal variability at Narsap Sermia, Greenland

Author

Van Wyk De Vries, Maximillian, Lea, James M., and Ashmore, David W.

Subjects

Earth-Surface Processes

Abstract

Mass loss from iceberg calving at marine-terminating glaciers is one of the largest and most poorly constrained contributors to sea-level rise. However, our understanding of the processes controlling ice fracturing and crevasse evolution is incomplete. Here, we use Gabor filter banks to automatically map crevasse density and orientation through time on a ~150 km2 terminus region of Narsap Sermia, an outlet glacier of the southwest Greenland ice sheet. We find that Narsap Sermia is dominated by transverse (flow-perpendicular) crevasses near the ice front and longitudinal (flow-aligned) crevasses across its central region. Measured crevasse orientation varies on sub-annual timescales by more than 45 $^\circ$ in response to seasonal velocity changes, and also on multi-annual timescales in response to broader dynamic changes and glacier retreat. Our results show a gradual up-glacier propagation of the zone of flow-transverse crevassing coincident with frontal retreat and acceleration occurring in 2020/21, in addition to sub-annual crevasse changes primarily in transition zones between longitudinal to transverse crevasse orientation. This provides new insight into the dynamics of crevassing at large marine-terminating glaciers and a potential approach for the rapid identification of glacier dynamic change from a single pair of satellite images.

Published

2022

2. Ice and firn heterogeneity within Larsen C Ice Shelf from borehole optical televiewing

Author

Ashmore, David W., Hubbard, Bryn, Luckman, Adrian, Kulessa, Bernd, Bevan, Suzanne, Booth, Adam, Munneke, Peter Kuipers, O'Leary, Martin, Sevestre, Heidi, Holland, Paul R., Sub Dynamics Meteorology, Marine and Atmospheric Research, and University of St Andrews. Geography & Sustainable Development

Subjects

G1, glaciology, Antarctica, G Geography (General), DAS, ice shelves

Abstract

Research was funded by the UK Natural Environmental Research Council grants NE/L006707/1 and NE/L005409/1 and a HEFCW/Aberystwyth University Capital Equipment Grant to B.H. Data will be available via the project website (www.projectmidas.org) and the UK Polar Data Centre (https://www.bas.ac.uk/data/uk-pdc/) from mid-2017. We use borehole optical televiewing (OPTV) to explore the internal structure of Larsen C Ice Shelf (LCIS). We report a suite of five ~90 m long OPTV logs, recording a light-emitting diode-illuminated, geometrically correct image of the borehole wall, from the northern and central sectors of LCIS collected during austral spring 2014 and 2015. We use a thresholding-based technique to estimate the refrozen ice content of the ice column and exploit a recently calibrated density-luminosity relationship to reveal its structure. All sites are dense and strongly influenced by surface melt, with frequent refrozen ice layers and mean densities, between the depths of 1.87 and 90 m, ranging from 862 to 894 kg m−3. We define four distinct units that comprise LCIS and relate these to ice provenance, dynamic history, and past melt events. These units are in situ meteoric ice with infiltration ice (U1), meteoric ice which has undergone enhanced densification (U2), thick refrozen ice (U3), and advected continental ice (U4). We show that the OPTV-derived pattern of firn air content is consistent with previous estimates, but that a significant proportion of firn air is contained within U4, which we interpret to have been deposited inland of the grounding line. The structure of LCIS is strongly influenced by the E-W gradient in föhn-driven melting, with sites close to the Antarctic Peninsula being predominantly composed of refrozen ice. Melting is also substantial toward the ice shelf center with >40% of the overall imaged ice column being composed of refrozen ice. Publisher PDF

Published

2017

3. Massive subsurface ice formed by refreezing of ice-shelf melt ponds

Author

Hubbard, Bryn, Luckman, Adrian, Ashmore, David W., Bevan, Suzanne, Kulessa, Bernd, Kuipers Munneke, Peter, Philippe, Morgane, Jansen, Daniela, Booth, Adam, Sevestre, Heidi, Tison, Jean-Louis, O'Leary, Martin, Rutt, Ian, Sub Dynamics Meteorology, and Marine and Atmospheric Research

Subjects

Science, Article

Abstract

Surface melt ponds form intermittently on several Antarctic ice shelves. Although implicated in ice-shelf break up, the consequences of such ponding for ice formation and ice-shelf structure have not been evaluated. Here we report the discovery of a massive subsurface ice layer, at least 16 km across, several kilometres long and tens of metres deep, located in an area of intense melting and intermittent ponding on Larsen C Ice Shelf, Antarctica. We combine borehole optical televiewer logging and radar measurements with remote sensing and firn modelling to investigate the layer, found to be ∼10 °C warmer and ∼170 kg m−3 denser than anticipated in the absence of ponding and hitherto used in models of ice-shelf fracture and flow. Surface ponding and ice layers such as the one we report are likely to form on a wider range of Antarctic ice shelves in response to climatic warming in forthcoming decades., The influence of surface ponding on the interior of ice shelves is currently unknown. Here, the authors combine surface and borehole geophysics on the Larsen C Ice Shelf, Antarctica, with remote sensing and modelling and show how pond refreezing increases ice shelf density and temperature.

Published

2016

4. Antarctic subglacial hydrology: an overview of current knowledge and forthcoming scientific challenges

Author

Ashmore, David W. and Bingham, Robert G.

Subjects

Antarctic ice sheet, geophysics, radio-echo sounding, glaciology, subglacial lakes, ice penetrating radar

Abstract

Flood-carved landforms across the deglaciated terrain of Victoria Land, East Antarctica, provide convincing geomorphological evidence for the existence of subglacial drainage networks beneath the Antarctic Ice Sheets, and motivate research into the inaccessible environment beneath the current ice sheet. Unlike at temperate glaciers, and more recently Arctic glaciers, where numerous researchers have explicitly studied “subglacial hydrology,” the acquisition of knowledge about subglacial hydrology in Antarctica has often been a side effect of geophysical and remote-sensing programmes targeted at multiple objectives. Through this research, however, we are steadily building an understanding of Antarctic subglacial hydrology, and this article presents an overview of the current state of knowledge. We first contextualise the discussion by introducing how our conceptualisation of subglacial hydrological behaviour has been developed at temperate and Arctic glaciers, but is less mature in the Antarctic, where our knowledge of subglacial-melt generation and variability, in particular, remain poorly constrained. We overview the discovery and progressive understanding of subglacial lake systems, whereby recent geophysical and remote-sensing observations have shown us that many lakes, once thought to be isolated and stable, form part of a highly dynamic network of subglacial drainage beneath the ice sheet. We then discuss some of the latest findings concerning subglacial water flows other than those directly concerned with lakes. Such water flows have potentially significant impacts on ice-stream dynamics, ice-sheet mass-balance, and supplies of water to the ocean potentially affecting circulation and nutrient productivity. We close by identifying some of the grand challenges that lie ahead for improving our understanding of these processes further.

Published

2014