Your search keyword '"Fricker, H.A."' showing total 19 results

1. Coincident Lake Drainage and Grounding Line Retreat at Engelhardt Subglacial Lake, West Antarctica

Author

Freer, B.I.D., Marsh, O.J., Fricker, H.A., Hogg, A.E., Siegfried, M.R., Floricioiu, D., Sauthoff, W., Rigby, R., Wilson, S.F., Freer, B.I.D., Marsh, O.J., Fricker, H.A., Hogg, A.E., Siegfried, M.R., Floricioiu, D., Sauthoff, W., Rigby, R., and Wilson, S.F.

Abstract

Antarctica has an active subglacial hydrological system, with interconnected subglacial lakes fed by subglacial meltwater. Subglacial hydrology can influence basal sliding, inject freshwater into the sub-ice-shelf cavity, and impact sediment transport and deposition which can affect the stability of grounding lines (GLs). We used satellite altimetry data from the ICESat, ICESat-2, and CryoSat-2 missions to document the second recorded drainage of Engelhardt Subglacial Lake (SLE), which began in July 2021 and discharged more than 2.3 km3 of subglacial water into the Ross Ice Shelf cavity. We used differential synthetic aperture radar interferometry from RADARSAT-2 and TerraSAR-X alongside ICESat-2 repeat-track laser altimetry (RTLA) and REMA digital elevation model strips to detect 2–13 km of GL retreat since the previous drainage event in 2003–06. Combining these satellite observations, we evaluated the mechanism triggering SLE drainage, the cause of the observed GL retreat, and the interplay between subglacial hydrology and GL dynamics. We find that: (a) SLE drainage was initiated by influx from a newly identified upstream lake; (b) the observed GL retreat is mainly driven by the continued retreat of Engelhardt Ice Ridge and long-term dynamic thinning that caused a grounded ice plain to reach flotation; and (c) SLE drainage and GL retreat were largely independent. We also discuss the possible origins and influence of a 27 km grounded promontory found to protrude seaward from the GL. Our observations demonstrate the importance of high-resolution satellite data for improving the process-based understanding of dynamic and complex regions around the Antarctic Ice Sheet margins.

Published

2024

2. How much, how fast?: A science review and outlook for research on the instability of Antarctica's Thwaites Glacier in the 21st century

Author

Scambos, T.A., Bell, R.E., Alley, R.B., Anandakrishnan, S., Bromwich, D.H., Brunt, K., Christianson, K., Creyts, T., Das, S.B., DeConto, R., Dutrieux, P., Fricker, H.A., Holland, D., MacGregor, J., Medley, B., Nicolas, J.P., Pollard, D., Siegfried, M.R., Smith, A.M., Steig, E.J., Trusel, L.D., Vaughan, D.G., and Yager, P.L.

Published

2017

3. Antarctic ice-sheet loss driven by basal melting of ice shelves

Author

Pritchard, H.D., Ligtenberg, S.R.M., Fricker, H.A., Vaughan, D.G., van den Broeke, M.R., and Padman, L.

Subjects

Antarctica -- Environmental aspects -- Research, Surface-ice melting -- Research, Sea level -- Forecasts and trends -- Research, Ice sheets -- Environmental aspects, Market trend/market analysis, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

Author(s): H. D. Pritchard (corresponding author) [1]; S. R. M. Ligtenberg [2]; H. A. Fricker [3]; D. G. Vaughan [1]; M. R. van den Broeke [2]; L. Padman [4] Accurate [...]

Published

2012

4. Choosing the future of Antarctica

Author

Rintoul, S.R., Chown, S.L., DeConto, R.M., England, M.H., Fricker, H.A., Masson-Delmotte, V., Naish, T.R., Siegert, M.J., Xavier, J.C., Rintoul, S.R., Chown, S.L., DeConto, R.M., England, M.H., Fricker, H.A., Masson-Delmotte, V., Naish, T.R., Siegert, M.J., and Xavier, J.C.

Abstract

We present two narratives on the future of Antarctica and the Southern Ocean, from the perspective of an observer looking back from 2070. In the first scenario, greenhouse gas emissions remained unchecked, the climate continued to warm, and the policy response was ineffective; this had large ramifications in Antarctica and the Southern Ocean, with worldwide impacts. In the second scenario, ambitious action was taken to limit greenhouse gas emissions and to establish policies that reduced anthropogenic pressure on the environment, slowing the rate of change in Antarctica. Choices made in the next decade will determine what trajectory is realized.

Published

2018

5. Subglacial channelized drainage on soft beds and implications for grounding-line dynamics

Author

Damsgaard, Anders, Suckale, Jenny, Piotrowski, Jan A., Houssais, M., Siegfried, Matthew, and Fricker, H.A.

Published

2017

6. Oceanic and atmospheric forcing of Larsen C Ice-Shelf thinning

Author

Holland, P.R., Brisbourne, A., Corr, H.F.J., McGrath, D., Purdon, K., Paden, J., Fricker, H.A., Paolo, F.S., Fleming, A.H., Holland, P.R., Brisbourne, A., Corr, H.F.J., McGrath, D., Purdon, K., Paden, J., Fricker, H.A., Paolo, F.S., and Fleming, A.H.

Abstract

The catastrophic collapses of Larsen A and B ice shelves on the eastern Antarctic Peninsula have caused their tributary glaciers to accelerate, contributing to sea-level rise and freshening the Antarctic Bottom Water formed nearby. The surface of Larsen C Ice Shelf (LCIS), the largest ice shelf on the peninsula, is lowering. This could be caused by unbalanced ocean melting (ice loss) or enhanced firn melting and compaction (englacial air loss). Using a novel method to analyse eight radar surveys, this study derives separate estimates of ice and air thickness changes during a 15-year period. The uncertainties are considerable, but the primary estimate is that the surveyed lowering (0.066 ± 0.017 m yr−1) is caused by both ice loss (0.28 ± 0.18 m yr−1) and firn-air loss (0.037 ± 0.026 m yr−1). The ice loss is much larger than the air loss, but both contribute approximately equally to the lowering because the ice is floating. The ice loss could be explained by high basal melting and/or ice divergence, and the air loss by low surface accumulation or high surface melting and/or compaction. The primary estimate therefore requires that at least two forcings caused the surveyed lowering. Mechanisms are discussed by which LCIS stability could be compromised in the future. The most rapid pathways to collapse are offered by the ungrounding of LCIS from Bawden Ice Rise or ice-front retreat past a "compressive arch" in strain rates. Recent evidence suggests that either mechanism could pose an imminent risk.

Published

2015

7. A roadmap for Antarctic and Southern Ocean science for the next two decades and beyond

Author

Kennicutt, M.C., Chown, S.L., Cassano, J.J., Liggett, D., Peck, L.S., Massom, R., Rintoul, S.R., Storey, J., Vaughan, D.G., Wilson, T.J., Allison, I., Ayton, J., Badhe, R., Baeseman, J., Barrett, P.J., Bell, R.E., Bertler, N., Bo, S., Brandt, A., Bromwich, D., Cary, S.C., Clark, M.S., Convey, P., Costa, E.S., Cowan, D., Deconto, R., Dunbar, R., Elfring, C., Escutia, C., Francis, J., Fricker, H.A., Fukuchi, M., Gilbert, N., Gutt, J., Havermans, C., Hik, D., Hosie, G., Jones, C., Kim, Y.D., Le Maho, Y., Lee, S.H., Leppe, M., Leitchenkov, G., Li, X., Lipenkov, V., Lochte, K., López-Martínez, J., Lüdecke, C., Lyons, W., Marenssi, S., Miller, H., Morozova, P., Naish, T., Nayak, S., Ravindra, R., Retamales, J., Ricci, C.A., Rogan-Finnemore, M., Ropert-Coudert, Y., Samah, A.A., Sanson, L., Scambos, T., Schloss, I.R., Shiraishi, K., Siegert, M.J., Simões, J.C., Storey, B., Sparrow, M.D., Wall, D.H., Walsh, J.C., Wilson, G., Winther, J.G., Xavier, J.C., Yang, H., Sutherland, W.J., Kennicutt, M.C., Chown, S.L., Cassano, J.J., Liggett, D., Peck, L.S., Massom, R., Rintoul, S.R., Storey, J., Vaughan, D.G., Wilson, T.J., Allison, I., Ayton, J., Badhe, R., Baeseman, J., Barrett, P.J., Bell, R.E., Bertler, N., Bo, S., Brandt, A., Bromwich, D., Cary, S.C., Clark, M.S., Convey, P., Costa, E.S., Cowan, D., Deconto, R., Dunbar, R., Elfring, C., Escutia, C., Francis, J., Fricker, H.A., Fukuchi, M., Gilbert, N., Gutt, J., Havermans, C., Hik, D., Hosie, G., Jones, C., Kim, Y.D., Le Maho, Y., Lee, S.H., Leppe, M., Leitchenkov, G., Li, X., Lipenkov, V., Lochte, K., López-Martínez, J., Lüdecke, C., Lyons, W., Marenssi, S., Miller, H., Morozova, P., Naish, T., Nayak, S., Ravindra, R., Retamales, J., Ricci, C.A., Rogan-Finnemore, M., Ropert-Coudert, Y., Samah, A.A., Sanson, L., Scambos, T., Schloss, I.R., Shiraishi, K., Siegert, M.J., Simões, J.C., Storey, B., Sparrow, M.D., Wall, D.H., Walsh, J.C., Wilson, G., Winther, J.G., Xavier, J.C., Yang, H., and Sutherland, W.J.

Abstract

Antarctic and Southern Ocean science is vital to understanding natural variability, the processes that govern global change and the role of humans in the Earth and climate system. The potential for new knowledge to be gained from future Antarctic science is substantial. Therefore, the international Antarctic community came together to ‘scan the horizon’ to identify the highest priority scientific questions that researchers should aspire to answer in the next two decades and beyond. Wide consultation was a fundamental principle for the development of a collective, international view of the most important future directions in Antarctic science. From the many possibilities, the horizon scan identified 80 key scientific questions through structured debate, discussion, revision and voting. Questions were clustered into seven topics: i) Antarctic atmosphere and global connections, ii) Southern Ocean and sea ice in a warming world, iii) ice sheet and sea level, iv) the dynamic Earth, v) life on the precipice, vi) near-Earth space and beyond, and vii) human presence in Antarctica. Answering the questions identified by the horizon scan will require innovative experimental designs, novel applications of technology, invention of next-generation field and laboratory approaches, and expanded observing systems and networks. Unbiased, non-contaminating procedures will be required to retrieve the requisite air, biota, sediment, rock, ice and water samples. Sustained year-round access to Antarctica and the Southern Ocean will be essential to increase winter-time measurements. Improved models are needed that represent Antarctica and the Southern Ocean in the Earth System, and provide predictions at spatial and temporal resolutions useful for decision making. A co-ordinated portfolio of cross-disciplinary science, based on new models of international collaboration, will be essential as no scientist, programme or nation can realize these aspirations alone.

Published

2015

8. Oceanic controls on the mass balance of Wilkins Ice Shelf, Antarctica

Author

Padman, L., Costa, D. P., Dinniman, M.S., Fricker, H.A., Goebel, M.E., Huckstadt, L.A., Humbert, A., Joughin, A., Lenaerts, J.T.M., Ligtenberg, S.R.M., Scambos, T., van den Broeke, M.R., Marine and Atmospheric Research, and Sub Dynamics Meteorology

Abstract

Several Antarctic Peninsula (AP) ice shelves have lost significant fractions of their volume over the past decades, coincident with rapid regional climate change. Wilkins Ice Shelf (WIS), on the western side of the AP, is the most recent, experiencing a sequence of large calving events in 2008 and 2009. We analyze the mass balance for WIS for the period 1992 2008 and find that the averaged rate of ice-shelf thinning was 0.8 m a 1, driven by a mean basal melt rate of 〈wb〉 = 1.3 0.4 m a 1. Interannual variability was large, associated with changes in both surface mass accumulation and 〈wb〉. Basal melt rate declined significantly around 2000 from 1.8 0.4 m a 1 for 1992–2000 to 0.75 0.55 m a 1 for 2001–2008; the latter value corresponding to approximately steady-state ice-shelf mass. Observations of ocean temperature T obtained during 2007–2009 by instrumented seals reveal a cold, deep halo of Winter Water (WW; T ≈ 1.6°C) surrounding WIS. The base of the WW in the halo is 170 m, approximately the mean ice draft for WIS. We hypothesize that the transition in 〈wb〉 in 2000 was caused by a small perturbation ( 10–20 m) in the relative depths of the ice base and the bottom of the WW layer in the halo. We conclude that basal melting of thin ice shelves like WIS is very sensitive to upper-ocean and coastal processes that act on shorter time and space scales than those affecting basal melting of thicker West Antarctic ice shelves such as George VI and Pine Island Glacier.

Published

2012

9. The structural and dynamic responses of Stange Ice Shelf to recent environmental change

Author

Holt, T.O., Glasser, N.F., Fricker, H.A., Padman, L., Luckman, A., King, Owen, Quincey, D.J., Siegfried, M.R., Holt, T.O., Glasser, N.F., Fricker, H.A., Padman, L., Luckman, A., King, Owen, Quincey, D.J., and Siegfried, M.R.

Abstract

Stange Ice Shelf is the most south-westerly ice shelf on the Antarctic Peninsula, a region where positive trends in atmospheric and oceanic temperatures have been recently documented. In this paper, we use a range of remotely sensed datasets to evaluate the structural and dynamic responses of Stange Ice Shelf to these environmental changes. Ice shelf extent and surface structures were examined at regular intervals from optical and radar satellite imagery between 1973 and 2011. Surface speeds were estimated in 1989, 2004 and 2010 by tracking surface features in successive satellite images. Surface elevation change was estimated using radar altimetry data acquired between 1992 and 2008 by the European Remote Sensing Satellite (ERS) -1, -2 and Envisat. The mean number of surface melt days was estimated using the intensity of backscatter from Envisat’s Advanced Synthetic Aperture Radar instrument between 2006 and 2012. These results show significant shear fracturing in the southern portion of the ice shelf linked to enhanced flow speed as a consequence of measured thinning. However, we conclude that, despite the observed changes, Stange Ice Shelf is currently stable.

Published

2014

10. A roadmap for Antarctic and Southern Ocean science for the next two decades and beyond

Author

Kennicutt II, M.C., Chown, S.L., Cassano, J.J., Liggett, D., Peck, L.S., Massom, R., Rintoul, S.R., Storey, J., Vaughan, D.G., Wilson, T.J., Allison, I., Ayton, J., Badhe, R., Baesemann, J., Barrett, P.J., Bell, R.E., Bertler, N., Bo, S., Brandt, A., Bromwich, D., Cary, S.C., Clark, M.S., Convey, P., Costa, E.S., Cowan, D., DeConto, R., Dunbar, R., Elfring, C., Escutia, C., Francis, J., Fricker, H.A., Fukuchi, M., Gilbert, N., Gutt, J., Havermans, C., Hik, D., Hosie, G., Jones, C., Kim, Y.D., Le Maho, Y., Lee, S.H., Leppe, M., Leitchenkov, G., Li, X., Lipenkov, V., Lochte, K., López-Martínez, J., Lüdecke, C., Lyons, W., Marenssi, S, Miller, H., Morozova, P., Naish, T., Nayak, S., Ravindra, R., Retamales, J., Ricci, C.A., Rogan-Finnemore, M., Ropert-Coudert, Y., Samah, A.A., Sanson, L., Scambos, T., Schloss, I.R., Shiraishi, K., Siegert, M.J., Simões, J.C., Storey, B., Sparrow, M.D., Wall, D.H., Walsh, J.C., Wilson, G., Winther, J.G., Xavier, J.C., Yang, H., Sutherland, W.J., Kennicutt II, M.C., Chown, S.L., Cassano, J.J., Liggett, D., Peck, L.S., Massom, R., Rintoul, S.R., Storey, J., Vaughan, D.G., Wilson, T.J., Allison, I., Ayton, J., Badhe, R., Baesemann, J., Barrett, P.J., Bell, R.E., Bertler, N., Bo, S., Brandt, A., Bromwich, D., Cary, S.C., Clark, M.S., Convey, P., Costa, E.S., Cowan, D., DeConto, R., Dunbar, R., Elfring, C., Escutia, C., Francis, J., Fricker, H.A., Fukuchi, M., Gilbert, N., Gutt, J., Havermans, C., Hik, D., Hosie, G., Jones, C., Kim, Y.D., Le Maho, Y., Lee, S.H., Leppe, M., Leitchenkov, G., Li, X., Lipenkov, V., Lochte, K., López-Martínez, J., Lüdecke, C., Lyons, W., Marenssi, S, Miller, H., Morozova, P., Naish, T., Nayak, S., Ravindra, R., Retamales, J., Ricci, C.A., Rogan-Finnemore, M., Ropert-Coudert, Y., Samah, A.A., Sanson, L., Scambos, T., Schloss, I.R., Shiraishi, K., Siegert, M.J., Simões, J.C., Storey, B., Sparrow, M.D., Wall, D.H., Walsh, J.C., Wilson, G., Winther, J.G., Xavier, J.C., Yang, H., and Sutherland, W.J.

Abstract

Antarctic and Southern Ocean science is vital to understanding natural variability, the processes that govern global change and the role of humans in the Earth and climate system. The potential for new knowledge to be gained from future Antarctic science is substantial. Therefore, the international Antarctic community came together to ‘scan the horizon’ to identify the highest priority scientific questions that researchers should aspire to answer in the next two decades and beyond. Wide consultation was a fundamental principle for the development of a collective, international view of the most important future directions in Antarctic science. From the many possibilities, the horizon scan identified 80 key scientific questions through structured debate, discussion, revision and voting. Questions were clustered into seven topics: i)Antarctic atmosphere and global connections, ii) Southern Ocean and sea ice in a warming world, iii) ice sheet and sea level, iv) the dynamic Earth, v) life on the precipice, vi) near-Earth space and beyond, and vii) human presence in Antarctica. Answering the questions identified by the horizon scan will require innovative experimental designs, novel applications of technology, invention of next-generation field and laboratory approaches, and expanded observing systems and networks. Unbiased, non-contaminating procedures will be required to retrieve the requisite air, biota, sediment, rock, ice and water samples. Sustained year-round access toAntarctica and the Southern Ocean will be essential to increase winter-time measurements. Improved models are needed that represent Antarctica and the Southern Ocean in the Earth System, and provide predictions at spatial and temporal resolutions useful for decision making. A co-ordinated portfolio of cross-disciplinary science, based on new models of international collaboration, will be essential as no scientist, programme or nation can realize these aspirations alone.

Published

2014

11. The structural and dynamic responses of Stange Ice Shelf to recent environmental change

Author

Holt, T.O., primary, Glasser, N.F., additional, Fricker, H.A., additional, Padman, L., additional, Luckman, A., additional, King, O., additional, Quincey, D.J., additional, and Siegfried, M.R., additional

Published

2014

12. A roadmap for Antarctic and Southern Ocean science for the next two decades and beyond

Author

Kennicutt, M.C., primary, Chown, S.L., additional, Cassano, J.J., additional, Liggett, D., additional, Peck, L.S., additional, Massom, R., additional, Rintoul, S.R., additional, Storey, J., additional, Vaughan, D.G., additional, Wilson, T.J., additional, Allison, I., additional, Ayton, J., additional, Badhe, R., additional, Baeseman, J., additional, Barrett, P.J., additional, Bell, R.E., additional, Bertler, N., additional, Bo, S., additional, Brandt, A., additional, Bromwich, D., additional, Cary, S.C., additional, Clark, M.S., additional, Convey, P., additional, Costa, E.S., additional, Cowan, D., additional, Deconto, R., additional, Dunbar, R., additional, Elfring, C., additional, Escutia, C., additional, Francis, J., additional, Fricker, H.A., additional, Fukuchi, M., additional, Gilbert, N., additional, Gutt, J., additional, Havermans, C., additional, Hik, D., additional, Hosie, G., additional, Jones, C., additional, Kim, Y.D., additional, Le Maho, Y., additional, Lee, S.H., additional, Leppe, M., additional, Leitchenkov, G., additional, Li, X., additional, Lipenkov, V., additional, Lochte, K., additional, López-Martínez, J., additional, Lüdecke, C., additional, Lyons, W., additional, Marenssi, S., additional, Miller, H., additional, Morozova, P., additional, Naish, T., additional, Nayak, S., additional, Ravindra, R., additional, Retamales, J., additional, Ricci, C.A., additional, Rogan-Finnemore, M., additional, Ropert-Coudert, Y., additional, Samah, A.A., additional, Sanson, L., additional, Scambos, T., additional, Schloss, I.R., additional, Shiraishi, K., additional, Siegert, M.J., additional, Simões, J.C., additional, Storey, B., additional, Sparrow, M.D., additional, Wall, D.H., additional, Walsh, J.C., additional, Wilson, G., additional, Winther, J.G., additional, Xavier, J.C., additional, Yang, H., additional, and Sutherland, W.J., additional

Published

2014

13. Antarctic ice-sheet loss driven by basal melting of ice shelves

Author

Marine and Atmospheric Research, Sub Dynamics Meteorology, Pritchard, H.D., Ligtenberg, S.R.M., Fricker, H.A., Vaughan, D.G., van den Broeke, M.R., Padman, L., Marine and Atmospheric Research, Sub Dynamics Meteorology, Pritchard, H.D., Ligtenberg, S.R.M., Fricker, H.A., Vaughan, D.G., van den Broeke, M.R., and Padman, L.

Published

2012

14. Oceanic controls on the mass balance of Wilkins Ice Shelf, Antarctica

Author

Marine and Atmospheric Research, Sub Dynamics Meteorology, Padman, L., Costa, D. P., Dinniman, M.S., Fricker, H.A., Goebel, M.E., Huckstadt, L.A., Humbert, A., Joughin, A., Lenaerts, J.T.M., Ligtenberg, S.R.M., Scambos, T., van den Broeke, M.R., Marine and Atmospheric Research, Sub Dynamics Meteorology, Padman, L., Costa, D. P., Dinniman, M.S., Fricker, H.A., Goebel, M.E., Huckstadt, L.A., Humbert, A., Joughin, A., Lenaerts, J.T.M., Ligtenberg, S.R.M., Scambos, T., and van den Broeke, M.R.

Published

2012

15. Evidence of rapid subglacial water piracy under Whillans Ice Stream, West Antarctica

Author

Carter, S.P., primary, Fricker, H.A., additional, and Siegfried, M.R., additional

Published

2013

16. The supply of subglacial meltwater to the grounding line of the Siple Coast, West Antarctica

Author

Carter, S.P., primary and Fricker, H.A., additional

Published

2012

17. Recommendations for the collection and synthesis of Antarctic Ice Sheet mass balance data

Author

Abdalati, W., Allison, I., Carsey, F., Casassa, G., Fily, M., Frezzotti, M., Fricker, H.A., Genthon, C., Goodwin, I., Guo, Z., Hamilton, G.S., Hindmarsh, R.C.A., Hulbe, C.L., Jacka, T.H., Jezek, K.C., Kwok, R., Li, J., Nixdorf, U., Paltridge, G., Rignot, E., Ritz, C., Satow, K., Scambos, T.A., Shuman, C., Skvarca, P., Takahashi, S., van de Wal, R.S.W., Vaughan, D.G., Wang, W.L., Warner, R.C., Wingham, D.J., Young, N.W., Zwally, H.J., Abdalati, W., Allison, I., Carsey, F., Casassa, G., Fily, M., Frezzotti, M., Fricker, H.A., Genthon, C., Goodwin, I., Guo, Z., Hamilton, G.S., Hindmarsh, R.C.A., Hulbe, C.L., Jacka, T.H., Jezek, K.C., Kwok, R., Li, J., Nixdorf, U., Paltridge, G., Rignot, E., Ritz, C., Satow, K., Scambos, T.A., Shuman, C., Skvarca, P., Takahashi, S., van de Wal, R.S.W., Vaughan, D.G., Wang, W.L., Warner, R.C., Wingham, D.J., Young, N.W., and Zwally, H.J.

Abstract

Recent unexpected changes in the Antarctic Ice Sheet, including ice sheet thinning, ice shelf collapse and changes in ice velocities, along with the recent realization that as much as one third of ice shelf mass loss is due to bottom melt, place a new urgency on understanding the processes involved in these changes. Technological advances, including very new or forthcoming satellite-based (e.g. ICESat, CryoSat) remote sensing missions, will improve our ability to make meaningful determinations of changes in Antarctic Ice Sheet mass balance. This paper is the result of a workshop held to develop a strategy for international collaboration aimed at the collection and synthesis of Antarctic Ice Sheet mass balance data, and at understanding the processes involved so that we might predict future change. Nine sets of recommendations are made, concerning the most important and sensitive measurements, temporal ranges and study areas. A final tenth recommendation calls for increased synthesis of ice sheet data and communication between the field measurement, satellite observation and modelling communities.

Published

2004

18. Ice sheet mass balance and sea level

Author

Allison, I., primary, Alley, R.B., additional, Fricker, H.A., additional, Thomas, R.H., additional, and Warner, R.C., additional

Published

2009

19. How much, how fast?: A science review and outlook for research on the instability of Antarctica's Thwaites Glacier in the 21st century

Author

Scambos, Ted A., Bell, Robin E., Alley, Richard B., Anandakrishnan, S., Bromwich, D.H., Brunt, K., Christianson., K., Creyts, Timothy T., Das, S.B., DeConto, Robert M., Dutrieux, Pierre, Fricker, H.A., Holland, D., MacGregor, J., Medley, B., Nicolas, Julien P., Pollard, D., Siegfried, M.R., Smith, A.M., Steig, E.J., Trusel, L.D., Vaughan, D.G., and Yager, P.L.

Subjects

13. Climate action, Glaciology, Sea level, 14. Life underwater, Climatic changes, Glaciers, Glaciers--Climatic factors

Abstract

Constraining how much and how fast the West Antarctic Ice Sheet (WAIS) will change in the coming decades has recently been identified as the highest priority in Antarctic research (National Academies, 2015). Here we review recent research on WAIS and outline further scientific objectives for the area now identified as the most likely to undergo near-term significant change: Thwaites Glacier and the adjacent Amundsen Sea. Multiple lines of evidence point to an ongoing rapid loss of ice in this region in response to changing atmospheric and oceanic conditions. Models of the ice sheet's dynamic behavior indicate a potential for greatly accelerated ice loss as ocean-driven melting at the Thwaites Glacier grounding zone and nearby areas leads to thinning, faster flow, and retreat. A complete retreat of the Thwaites Glacier basin would raise global sea level by more than three meters by entraining ice from adjacent catchments. This scenario could occur over the next few centuries, and faster ice loss could occur through processes omitted from most ice flow models such as hydrofracture and ice cliff failure, which have been observed in recent rapid ice retreats elsewhere. Increased basal melt at the grounding zone and increased potential for hydrofracture due to enhanced surface melt could initiate a more rapid collapse of Thwaites Glacier within the next few decades.