Your search keyword '"Wallis, Benjamin J."' showing total 14 results

1. Ocean warming drives rapid dynamic activation of marine-terminating glacier on the west Antarctic Peninsula

Author

Wallis, Benjamin J., Hogg, Anna E., Meredith, Michael P., Close, Romilly, Hardy, Dominic, McMillan, Malcolm, Wuite, Jan, Nagler, Thomas, and Moffat, Carlos

Published

2023

2. Widespread seasonal speed-up of west Antarctic Peninsula glaciers from 2014 to 2021

Author

Wallis, Benjamin J., Hogg, Anna E., van Wessem, J. Melchior, Davison, Benjamin J., and van den Broeke, Michiel R.

Published

2023

3. Widespread increase in discharge from west Antarctic Peninsula glaciers since 2018.

Author

Davison, Benjamin J., Hogg, Anna E., Moffat, Carlos, Meredith, Michael P., and Wallis, Benjamin J.

Subjects

ANTARCTIC glaciers, ACCELERATION (Mechanics), ATMOSPHERIC temperature, OCEAN temperature, OCEAN circulation, ALPINE glaciers, GLACIERS

Abstract

Many glaciers on the Antarctic Peninsula have retreated and accelerated in recent decades. Here we show that there has been a widespread, quasi-synchronous, and sustained increase in grounding line discharge from glaciers on the west coast of the Antarctic Peninsula since 2018. Overall, the west Antarctic Peninsula discharge trends increased by over a factor of 3, from 50 Mtyr-2 during 2017 to 2020 up to 160 Mtyr-2 in the years following, leading to a 7.4 % increase in grounding line discharge since 2017. The acceleration in discharge was concentrated at glaciers connected to deep, cross-shelf troughs hosting warm-ocean waters, and the acceleration occurred during a period of anomalously high subsurface water temperatures on the continental shelf. Given that many of the affected glaciers have retreated over the past several decades in response to ocean warming, thereby highlighting their sensitivity to ocean forcing, we argue that the recent period of anomalously warm water was likely a key driver of the observed acceleration. However, the acceleration also occurred during a time of anomalously high atmospheric temperatures and glacier surface runoff, which could have contributed to speed-up by directly increasing basal water pressure and, by invigorating near-glacier ocean circulation, increasing submarine melt rates. The spatial pattern of glacier acceleration therefore provides an indication of glaciers that are exposed to warm-ocean water at depth and/or have active surface-to-bed hydrological connections; however, many stages in the chain of events leading to glacier acceleration, and how that response is affected by glacier-specific factors, remain insufficiently understood. Both atmospheric and ocean temperatures in this region and its surroundings are likely to increase further in the coming decades; therefore, there is a pressing need to improve our understanding of recent changes in Antarctic Peninsula glacier dynamics in response atmospheric and oceanic changes in order to improve projections of their behaviour over the coming century. [ABSTRACT FROM AUTHOR]

Published

2024

4. Widespread increase in discharge from West Antarctic Peninsula glaciers since 2018

Author

Davison, Benjamin J., primary, Hogg, Anna E., additional, Moffat, Carlos, additional, Meredith, Michael P., additional, and Wallis, Benjamin J., additional

Published

2024

5. The effect of landfast sea ice buttressing on ice dynamic speedup in the Larsen B embayment, Antarctica.

Author

Surawy-Stepney, Trystan, Hogg, Anna E., Cornford, Stephen L., Wallis, Benjamin J., Davison, Benjamin J., Selley, Heather L., Slater, Ross A. W., Lie, Elise K., Jakob, Livia, Ridout, Andrew, Gourmelen, Noel, Freer, Bryony I. D., Wilson, Sally F., and Shepherd, Andrew

Subjects

ICE shelves, SEA ice, GLACIERS, GLACIER speed, OCEAN waves, ICE streams, WEATHER, STRESS concentration

Abstract

We observe the evacuation of 11-year-old landfast sea ice in the Larsen B embayment on the East Antarctic Peninsula in January 2022, which was in part triggered by warm atmospheric conditions and strong offshore winds. This evacuation of sea ice was closely followed by major changes in the calving behaviour and dynamics of a subset of the ocean-terminating glaciers in the region. We show using satellite measurements that, following a decade of gradual slow-down, Hektoria, Green, and Crane glaciers sped up by approximately 20 %–50 % between February and the end of 2022, each increasing in speed by more than 100 ma-1. Circumstantially, this is attributable to their transition into tidewater glaciers following the loss of their ice shelves after the landfast sea ice evacuation. However, a question remains as to whether the landfast sea ice could have influenced the dynamics of these glaciers, or the stability of their ice shelves, through a buttressing effect akin to that of confined ice shelves on grounded ice streams. We show, with a series of diagnostic modelling experiments, that direct landfast sea ice buttressing had a negligible impact on the dynamics of the grounded ice streams. Furthermore, we suggest that the loss of landfast sea ice buttressing could have impacted the dynamics of the rheologically weak ice shelves, in turn diminishing their stability over time; however, the accompanying shifts in the distributions of resistive stress within the ice shelves would have been minor. This indicates that this loss of buttressing by landfast sea ice is likely to have been a secondary process in the ice shelf disaggregation compared to, for example, increased ocean swell or the drivers of the initial landfast sea ice disintegration. [ABSTRACT FROM AUTHOR]

Published

2024

6. Supplementary material to "The impact of landfast sea ice buttressing on ice dynamic speedup in the Larsen-B Embayment, Antarctica"

Author

Surawy-Stepney, Trystan, primary, Hogg, Anna E., additional, Cornford, Stephen L., additional, Wallis, Benjamin J., additional, Davison, Benjamin J., additional, Selley, Heather L., additional, Slater, Ross A. W., additional, Lie, Elise K., additional, Jakob, Livia, additional, Ridout, Andrew L., additional, Gourmelen, Noel, additional, Freer, Bryony I. D., additional, Wilson, Sally F., additional, and Shepherd, Andrew, additional

Published

2023

7. The impact of landfast sea ice buttressing on ice dynamic speedup in the Larsen-B Embayment, Antarctica

Author

Surawy-Stepney, Trystan, primary, Hogg, Anna E., additional, Cornford, Stephen L., additional, Wallis, Benjamin J., additional, Davison, Benjamin J., additional, Selley, Heather L., additional, Slater, Ross A. W., additional, Lie, Elise K., additional, Jakob, Livia, additional, Ridout, Andrew L., additional, Gourmelen, Noel, additional, Freer, Bryony I. D., additional, Wilson, Sally F., additional, and Shepherd, Andrew, additional

Published

2023

8. Widespread increase in discharge from West Antarctic Peninsula glaciers since 2018.

Author

Davison, Benjamin J., Hogg, Anna E., Moffat, Carlos, Meredith, Michael P., and Wallis, Benjamin J.

Subjects

ANTARCTIC glaciers, GLACIERS, OCEAN temperature, MELTWATER, SEAWATER, ATMOSPHERIC temperature, WATER pressure

Abstract

Many glaciers on the Antarctic Peninsula have retreated and accelerated in recent decades. Here we show that there was a widespread, quasi-synchronous and sustained increase in grounding line discharge from glaciers on the west coast of the Antarctic Peninsula since 2018. Overall, west Antarctic Peninsula discharge trends increased by over a factor of three, from 0.5 Gt/y/decade during 2017 to 2020 up to 1.6 Gt/y/decade in the years following, leading to a grounding line discharge increase of 7 Gt/y (7.4 %) since 2017. The acceleration in discharge was concentrated at glaciers connected to deep, cross-shelf troughs hosting warm ocean waters, and the acceleration occurred during a period of anomalously high subsurface water temperatures on the continental shelf. Given that many of the affected glaciers have retreated over the past several decades in response to ocean warming, thereby highlighting their sensitivity to ocean forcing, we argue that the recent period of anomalously warm water was likely a key driver of the observed acceleration. However, the acceleration also occurred during a time of anomalously high atmospheric temperatures and glacier surface runoff, which could have contributed to speed-up by directly increasing basal water pressure and, by invigorating near-glacier circulation, increasing submarine melt rates. The spatial pattern of glacier acceleration therefore provides an indication of glaciers that are exposed to warm ocean water at depth and/or have active surface-to-bed hydrological connections. Both atmospheric and ocean temperatures in this region and its surroundings are likely to increase further in the coming decades, suggesting that discharge increases may continue and become more widespread. [ABSTRACT FROM AUTHOR]

Published

2024

9. Change in grounding line location on the Antarctic Peninsula measured using a tidal motion offset correlation method.

Author

Wallis, Benjamin J., Hogg, Anna E., Zhu, Yikai, and Hooper, Andrew

Subjects

ICE shelves, ANTARCTIC glaciers, ANTARCTIC ice, ICE sheets, SYNTHETIC aperture radar, ICE streams

Abstract

The grounding line position of glaciers and ice shelves is an essential observation for the study of the Earth's ice sheets. However, in some locations, such as the Antarctic Peninsula, where many grounding lines have not been mapped since the 1990s, remote sensing of grounding line position remains challenging. Here we present a tidal motion offset correlation (TMOC) method for measuring the grounding line position of tidewater glaciers and ice shelves, based on the correlation between tide amplitude and synthetic aperture radar offset tracking measurements. We apply this method to the Antarctic Peninsula Ice Sheet to automatically delineate a new grounding line position for 2019–2020, with near complete coverage along 9,300 km of coastline, updating the 20-year-old record. A comparison of the TMOC grounding line to contemporaneous interferometrically-measured grounding line position shows the method has a mean seaward offset compared to interferometry of 185 m and a standard deviation of 295 m. Our results show that over the last 24 years there has been grounding line retreat at a number of fast flowing ice streams on the Antarctic Peninsula, with the most retreat concentrated in the north-eastern sector, where grounding lines have retreated following the collapse of ice shelves. We observe a maximum grounding line retreat since 1996 of 16.3 km on Hektoria Glacier, with other notable glaciers retreating by 9.3 km, 9.1 km, and 3.6 km respectively. Our results document dynamic change on Antarctic Peninsula glaciers and show the importance of using an updated grounding line location to delineate the boundary between floating and grounded ice. [ABSTRACT FROM AUTHOR]

Published

2024

10. Ocean warming drives rapid dynamic activation of a marine-terminating glacier on the west Antarctic Peninsula

Author

Wallis, Benjamin J., Hogg, Anne E., Meredith, Michael P., Close, Romilly, Hardy, Dominic, McMillan, Malcolm, Wuite, Jan, Nagler, Thomas, Moffat, Carlos, Wallis, Benjamin J., Hogg, Anne E., Meredith, Michael P., Close, Romilly, Hardy, Dominic, McMillan, Malcolm, Wuite, Jan, Nagler, Thomas, and Moffat, Carlos

Abstract

Ice dynamic change is the primary cause of mass loss from the Antarctic Ice Sheet, thus it is important to understand the processes driving ice-ocean interactions and the timescale on which major change can occur. Here we use satellite observations to measure a rapid increase in speed and collapse of the ice shelf fronting Cadman Glacier in the absence of surface meltwater ponding. Between November 2018 and December 2019 ice speed increased by 94 ± 4% (1.47 ± 0.6 km/yr), ice discharge increased by 0.52 ± 0.21 Gt/yr, and the calving front retreated by 8 km with dynamic thinning on grounded ice of 20.1 ± 2.6 m/yr. This change was concurrent with a positive temperature anomaly in the upper ocean, where a 400 m deep channel allowed warm water to reach Cadman Glacier driving the dynamic activation, while neighbouring Funk and Lever Glaciers were protected by bathymetric sills across their fjords. Our results show that forcing by warm ocean water can cause the rapid onset of dynamic imbalance and increased ice discharge from glaciers on the Antarctic Peninsula, highlighting the region’s sensitivity to future climate variability.

Published

2023

11. Widespread seasonal speed-up of west Antarctic Peninsula glaciers from 2014 to 2021

Author

Sub Dynamics Meteorology, Marine and Atmospheric Research, Wallis, Benjamin J., Hogg, Anna E., van Wessem, J. Melchior, Davison, Benjamin J., van den Broeke, Michiel R., Sub Dynamics Meteorology, Marine and Atmospheric Research, Wallis, Benjamin J., Hogg, Anna E., van Wessem, J. Melchior, Davison, Benjamin J., and van den Broeke, Michiel R.

Published

2023

12. The impact of landfast sea ice buttressing on ice dynamic speedup in the Larsen-B Embayment, Antarctica.

Author

Surawy-Stepney, Trystan, Hogg, Anna E., Cornford, Stephen L., Wallis, Benjamin J., Davison, Benjamin J., Selley, Heather L., Slater, Ross A. W., Lie, Elise K., Jakob, Livia, Ridout, Andrew, Gourmelen, Noel, Freer, Bryony I. D., Wilson, Sally F., and Shepherd, Andrew

Abstract

We observe the evacuation of 11-year old landfast sea ice in the Larsen-B Embayment on the East Antarctic Peninsula in January 2022, which was in part triggered by warm atmospheric conditions and strong offshore winds. This evacuation of sea ice was closely followed by major changes in the calving behaviour and dynamics of the ocean-terminating glaciers in the region. Following a decade of gradual slow-down, satellite measurements show that Hektoria, Green and Crane Glaciers have sped up by approximately 20-50% since February 2022, each increasing in speed by more than 100 ma-1. Circumstantially, this is attributable to the loss of floating ice/mélange tongues and their transition into tidewater glaciers. However, a question remains as to whether the landfast sea ice itself could have acted to provide direct buttressing to the glaciers prior to its disintegration. We use diagnostic model simulations to estimate the buttressing effect of the landfast sea ice in the Larsen-B Embayment and its impact on the speed of Hektoria, Green, Evans and Crane Glaciers. The results show that direct sea ice buttressing had a negligible impact on the dynamics of the grounded ice streams. Additionally, our results show that the loss of sea ice buttressing likely produced noticeable changes to the flow speeds of the rheologically weak ice tongues, which could have diminished their stability over time. However, as the accompanying changes in viscous stress were small compared to local spatial variation, this loss of buttressing is likely to have been a secondary process in the disintegration of the ice tongues compared to, for example, increased ocean melting or swell. [ABSTRACT FROM AUTHOR]

Published

2023

13. Internal tsunamigenesis and ocean mixing driven by glacier calving in Antarctica

Author

Meredith, Michael P., Inall, Mark E., Brearley, J. Alexander, Ehmen, Tobias, Sheen, Katy, Munday, David, Cook, Alison, Retallick, Katherine, Van Landeghem, Katrien, Gerrish, Laura, Annett, Amber, Carvalho, Filipa, Jones, Rhiannon, Naveira Garabato, Alberto C., Bull, Christopher Y. S., Wallis, Benjamin J., Hogg, Anna E., and Scourse, James

Subjects

Multidisciplinary

Abstract

Ocean mixing around Antarctica exerts key influences on glacier dynamics and ice shelf retreats, sea ice, and marine productivity, thus affecting global sea level and climate. The conventional paradigm is that this is dominated by winds, tides, and buoyancy forcing. Direct observations from the Antarctic Peninsula demonstrate that glacier calving triggers internal tsunamis, the breaking of which drives vigorous mixing. Being widespread and frequent, these internal tsunamis are at least comparable to winds, and much more important than tides, in driving regional shelf mixing. They are likely relevant everywhere that marine-terminating glaciers calve, including Greenland and across the Arctic. Calving frequency may change with higher ocean temperatures, suggesting possible shifts to internal tsunamigenesis and mixing in a warming climate.

Published

2022

14. Internal tsunamigenesis and ocean mixing driven by glacier calving in Antarctica

Author

Meredith, Michael P., primary, Inall, Mark E., additional, Brearley, J. Alexander, additional, Ehmen, Tobias, additional, Sheen, Katy, additional, Munday, David, additional, Cook, Alison, additional, Retallick, Katherine, additional, Van Landeghem, Katrien, additional, Gerrish, Laura, additional, Annett, Amber, additional, Carvalho, Filipa, additional, Jones, Rhiannon, additional, Naveira Garabato, Alberto C., additional, Bull, Christopher Y. S., additional, Wallis, Benjamin J., additional, Hogg, Anna E., additional, and Scourse, James, additional

Published

2022