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298 results on '"Kulessa, Bernd"'

1. The drainage of glacier and ice sheet surface lakes

Author

Schoof, Christian, Cook, Sue, Kulessa, Bernd, and Thompson, Sarah

Subjects
Physics - Fluid Dynamics, Physics - Geophysics
Abstract

Supraglacial lakes play a central role in storing melt water, enhancing surface melt, and ultimately in driving ice flow and ice shelf melt through injecting water into the subglacial environment and facilitating fracturing. Here, we develop a model for the drainage of supraglacial lakes through the dissipation-driven incision of a surface channel. The model consists of the St Venant equations for flow in the channel, fed by an upstream lake reservoir, coupled with an equation for the evolution of channel elevation due to advection, uplift, and downward melting. After reduction to a `stream power'-type hyperbolic model, we show that lake drainage occurs above a critical rate of water supply to the lake due to the backward migration of a shock that incises the lake seal. The critical water supply rate depends on advection velocity and uplift (or more precisely, drawdown downstream of the lake) as well as model parameters such as channel wall roughness and the parameters defining the relationship between channel cross-section and wetted perimeter. Once lake drainage does occur, it can either continue until the lake is empty, or terminate early, leading to oscillatory cycles of lake filling and draining, with the latter favoured by large lake volumes and relatively small water supply rates.

Published
2021

5. Towards the systematic reconnaissance of seismic signals from glaciers and ice sheets – Part 2: Unsupervised learning for source process characterization.

Author

Latto, Rebecca B., Turner, Ross J., Reading, Anya M., Cook, Sue, Kulessa, Bernd, and Winberry, J. Paul

Subjects
ICE sheets, ICE shelves, RECONNAISSANCE operations, ICE streams, GLACIERS, SEISMIC waves, MELTWATER, WAVE analysis
Abstract

Given the high number and diversity of events in a typical cryoseismic dataset, in particular those recorded on ice sheet margins, it is desirable to use a semi-automated method of grouping similar events for reconnaissance and ongoing analysis. We present a workflow for employing semi-unsupervised cluster analysis to inform investigations of the processes occurring in glaciers and ice sheets. In this demonstration study, we make use of a seismic event catalogue previously compiled for the Whillans Ice Stream, for the 2010–2011 austral summer outlined in Part 1,. We address the challenges of seismic event analysis for a complex wave field by clustering similar seismic events into groups using characteristic temporal, spectral, and polarization attributes of seismic time series with the k -means++ algorithm. This provides the basis for a reconnaissance analysis of a seismic wave field that contains local events (from the ice stream) set in an ambient wave field that itself contains a diversity of signals (mostly from the Ross Ice Shelf). As one result, we find that two clusters include stick-slip events that diverge in terms of length and initiation locality (i.e., central sticky spot and/or the grounding line). We also identify a swarm of high-frequency signals on 16–17 January 2011 that are potentially associated with a surface melt event from the Ross Ice Shelf. Used together with the event detection presented in Part 1, the semi-automated workflow could readily be generalized to other locations and, as a possible benchmark procedure, could enable the monitoring of remote glaciers over time and comparisons between locations. [ABSTRACT FROM AUTHOR]

Published
2024
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6. Assessing the potential for ice flow piracy between the Totten and Vanderford glaciers, East Antarctica

Author

McCormack, Felicity S., primary, Roberts, Jason L., additional, Kulessa, Bernd, additional, Aitken, Alan, additional, Dow, Christine F., additional, Bird, Lawrence, additional, Galton-Fenzi, Benjamin K., additional, Hochmuth, Katharina, additional, Jones, Richard S., additional, Mackintosh, Andrew N., additional, and McArthur, Koi, additional

Published
2023
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7. Antarctic sedimentary basins and their influence on ice sheet dynamics

Author

Aitken, Alan R.A., primary, Li, Lu, additional, Kulessa, Bernd, additional, Schroeder, Dustin M, additional, Jordan, Tom A., additional, Whittaker, Joanne M, additional, Anandakrishnan, Sridhar, additional, Dawson, Eliza J, additional, Wiens, Douglas A, additional, Eisen, Olaf, additional, and Siegert, Martin J., additional

Published
2023
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10. Assessing the potential for ice flow piracy between Totten and Vanderford glaciers, East Antarctica

Author

McCormack, Felicity S., Roberts, Jason L., Kulessa, Bernd, Aitken, Alan, Dow, Christine F., Bird, Lawrence, Galton-Fenzi, Ben K., Hochmuth, Katharina, Jones, Richard S., Mackintosh, Andrew N., and McArthur, Koi

Abstract

The largest regional drivers of current surface elevation increases in the Antarctic Ice Sheet are associated with ice flow reconfiguration in previously active ice streams, highlighting the important role of ice dynamics in responding to climate change. Here, we investigate controls on the evolution of the flow configuration of the Vanderford and Totten Glaciers – key outlet glaciers of the Aurora Subglacial Basin, the most rapidly thinning region of the East Antarctic Ice Sheet. We review factors that influence the ice flow in this region, and use an ice sheet model to investigate the sensitivity of the catchment divide location to thinning at Vanderford Glacier associated with ongoing retreat, and thickening at Totten Glacier associated with an intensification of the east-west snowfall gradient. The present-day catchment divide between the Totten and Vanderford Glaciers is not constrained by the geology or topography, but is determined by the large-scale ice sheet geometry and its long-term evolution in response to climate forcing. Furthermore, the catchment divide is subject to migration under relatively small changes in surface elevation, leading to ice flow and basal water piracy from Totten to Vanderford Glacier. Our findings show that ice flow reconfigurations do not only occur in regions of West Antarctica like the Siple Coast, but also in the east, motivating further investigations of past, and potential for future, ice flow reconfigurations around the whole Antarctic coastline. Such modelling of ice flow and basal water piracy may require coupled ice sheet thermomechanical and subglacial hydrology models, constrained by field observations of subglacial conditions. Our results also have implications for ice sheet mass budget studies that integrate over catchments, and the validity of the zero flow assumption when selecting sites for ice core records of past climate.

Published
2023

14. Towards a common terminology in radioglaciology

Author

Schlegel, Rebecca, Kulessa, Bernd, Murray, Tavi, Eisen, Olaf, Schlegel, Rebecca, Kulessa, Bernd, Murray, Tavi, and Eisen, Olaf

Abstract

Over the past 70 years, many different components of the cryosphere have been imaged with a variety of radar systems using increasingly sophisticated processing techniques. These systems use various pulse lengths, signal frequencies and, in some cases, modulated signals. The increasing diversity of radar systems has created the potential for confusion due to the use of non-consistent terminology. Here we provide an overview of state-of-the-science radar technologies and suggest a simplified and unified terminology for use by the cryosphere community. We recommend a terminology that is target independent but specifies the characteristics of the signal. Following this recommendation, commercial impulse systems that penetrate the subsurface should be referred to as ground-penetrating radar (GPR), and pulse radars as radio-echo sounding (RES). Continuous-wave (CW) radar systems should be referred to as ground-penetrating CW radars. We further suggest any additional characterisation of the system be expressed using descriptors that specify the platform it is mounted on (e.g. airborne) or the frequency range (e.g. HF (high frequency)) or modulation (e.g. FM (frequency modulated)).

Published
2023

15. Geological sketch map and implications for ice flow of Thwaites Glacier, West Antarctica, from integrated aerogeophysical observations

Author

Jordan, Tom A., Thompson, Sarah, Kulessa, Bernd, Ferraccioli, Fausto, Jordan, Tom A., Thompson, Sarah, Kulessa, Bernd, and Ferraccioli, Fausto

Abstract

The geology beneath Thwaites Glacier, the Antarctic glacial catchment most vulnerable to climate change, is unknown. Thwaites Glacier lies within the West Antarctic Rift System, but details of the subglacial geology relevant to glacial flow, including sediment availability, underlying lithology, and heat flux, are lacking. We present the first sketch map of the subglacial geology of Thwaites Glacier, interpreted from maps of airborne gravity, magnetic and radar data, supported by 2D models and 3D inversion of subsurface properties, and the regional geological context. A zone of Cretaceous mafic magmatism extending ~200 km inland from the coast is interpreted, while sedimentary basins are restricted to a region 150 to 200 km inboard of the coast, underlying just 20% of the catchment. Several granitic subglacial highlands are identified, forming long-lived topographic highs. Our geological interpretation places constraints on the basal properties of Thwaites Glacier, laying the foundation for both improved predictions of ice sheet change and studies of West Antarctic tectonics.

Published
2023

16. Extraction and applications of Rayleigh wave ellipticity in polar regions

Author

European Commission, Agencia Estatal de Investigación (España), Jones, Glenn A., Kulessa, Bernd, Ferreira, A. M. G., Schimmel, Martin, Berbellini, Andrea, Morelli, Andrea, European Commission, Agencia Estatal de Investigación (España), Jones, Glenn A., Kulessa, Bernd, Ferreira, A. M. G., Schimmel, Martin, Berbellini, Andrea, and Morelli, Andrea

Abstract

Seismic Rayleigh wave ellipticity measurements are the horizontal-to-vertical ratio of the Rayleigh wave particle motion, and are sensitive to the subsurface structure beneath a seismic station. H/V ratios measured from the ambient vibrations of the Earth are being increasingly used in glaciological applications to determine glacier and ice sheet thickness, seismic velocities and firn properties. Using the newly developed degree-of-polarisation (DOP-E) method which exploits the polarisation properties of seismic noise, we identify and extract Rayleigh waves from seismic stations in Greenland, and relate them to sea ice processes and the geology of the upper crust. Finally, we provide some suggestions for future applications of DOP-E method to gain greater insight into seasonal and long-term variability of sea ice formation and breakup as well as the monitoring of ice sheet thickness, subglacial environment and firn layers in the poles.

Published
2023

17. Extraction and applications of Rayleigh wave ellipticity in polar regions.

Author

Jones, Glenn A., Kulessa, Bernd, Ferreira, Ana M. G., Schimmel, Martin, Berbellini, Andrea, and Morelli, Andrea

Subjects
*SEISMIC waves, *RAYLEIGH waves, *PARTICLE motion, *SEA ice, *ICE sheets, *MICROSEISMS
Abstract

Seismic Rayleigh wave ellipticity measurements are the horizontal-to-vertical ratio of the Rayleigh wave particle motion, and are sensitive to the subsurface structure beneath a seismic station. H/V ratios measured from the ambient vibrations of the Earth are being increasingly used in glaciological applications to determine glacier and ice sheet thickness, seismic velocities and firn properties. Using the newly developed degree-of-polarisation (DOP-E) method which exploits the polarisation properties of seismic noise, we identify and extract Rayleigh waves from seismic stations in Greenland, and relate them to sea ice processes and the geology of the upper crust. Finally, we provide some suggestions for future applications of DOP-E method to gain greater insight into seasonal and long-term variability of sea ice formation and breakup as well as the monitoring of ice sheet thickness, subglacial environment and firn layers in the poles. [ABSTRACT FROM AUTHOR]

Published
2023
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20. Glaciological history and structural evolution of the Shackleton Ice Shelf system, East Antarctica, over the past 60 years

Author

Thompson, Sarah S., primary, Kulessa, Bernd, additional, Luckman, Adrian, additional, Halpin, Jacqueline A., additional, Greenbaum, Jamin S., additional, Pelle, Tyler, additional, Habbal, Feras, additional, Guo, Jingxue, additional, Jong, Lenneke M., additional, Roberts, Jason L., additional, Sun, Bo, additional, and Blankenship, Donald D., additional

Published
2023
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23. Towards the systematic reconnaissance of seismic signals from glaciers and ice sheets – Part B: Unsupervised learning for source process characterisation.

Author

Latto, Rebecca B., Turner, Ross J., Reading, Anya M., Cook, Sue, Kulessa, Bernd, and Winberry, J. Paul

Subjects
ICE sheets, ICE shelves, GLACIERS, RECONNAISSANCE operations, ICE streams, TIME series analysis
Abstract

Given the high number and diversity of events in a typical cryoseismic dataset, in particular those recorded on ice sheet margins, it is desirable to use a semi-automated method of grouping similar events for reconnaissance and ongoing analysis. We present a workflow for employing semi-unsupervised cluster analysis to inform investigations of the processes occurring in glaciers and ice sheets. In this demonstration study, we make use of a seismic event catalogue previously compiled for the Whillans Ice Stream, for the 2010–2011 austral summer (outlined in companion paper, Latto et al., 2023). We address the challenges of seismic event analysis for a complex wavefield by clustering similar seismic events into groups using characteristic temporal, spectral, and polarization attributes of seismic time series with the k-means++ algorithm. This provides the basis for a reconnaissance analysis of a seismic wavefield that contains local events (from the ice stream) set in an ambient wavefield that itself contains a diversity of signals (mostly from the Ross Ice Shelf). As one result, we find that two clusters include stick-slip events that diverge in terms of length and initiation locality (i.e. Central Sticky Spot and/or the grounding line). We also identify a swarm of high frequency signals on January 16–17, 2011 that are potentially associated with a surface melt event from the Ross Ice Shelf. Used together with the event detection presented in the companion paper, the semi-automated workflow could readily generalize to other locations, and as a possible benchmark procedure, could enable the monitoring of remote glaciers over time and comparisons between locations. [ABSTRACT FROM AUTHOR]

Published
2023
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33. Towards a common terminology in radioglaciology.

Author

Schlegel, Rebecca, Kulessa, Bernd, Murray, Tavi, and Eisen, Olaf

Subjects
*GROUND penetrating radar, *CONTINUOUS wave radar, *TERMS & phrases, *RADAR, *CRYOSPHERE
Abstract

Over the past 70 years, many different components of the cryosphere have been imaged with a variety of radar systems using increasingly sophisticated processing techniques. These systems use various pulse lengths, signal frequencies and, in some cases, modulated signals. The increasing diversity of radar systems has created the potential for confusion due to the use of non-consistent terminology. Here we provide an overview of state-of-the-science radar technologies and suggest a simplified and unified terminology for use by the cryosphere community. We recommend a terminology that is target independent but specifies the characteristics of the signal. Following this recommendation, commercial impulse systems that penetrate the subsurface should be referred to as ground-penetrating radar (GPR), and pulse radars as radio-echo sounding (RES). Continuous-wave (CW) radar systems should be referred to as ground-penetrating CW radars. We further suggest any additional characterisation of the system be expressed using descriptors that specify the platform it is mounted on (e.g. airborne) or the frequency range (e.g. HF (high frequency)) or modulation (e.g. FM (frequency modulated)). [ABSTRACT FROM AUTHOR]

Published
2022
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35. Towards the development of an automated electrical self-potential sensor of melt and rainwater flow in snow.

Author

Priestley, Alex, Kulessa, Bernd, Essery, Richard, Lejeune, Yves, Le Gac, Erwan, and Blackford, Jane

Subjects
METEOROLOGICAL observations, WATER harvesting, SNOWMELT, MELTING, DETECTORS, PHYSICS, RAINWATER
Abstract

To understand snow structure and snowmelt timing, information about flows of liquid water within the snowpack is essential. Models can make predictions using explicit representations of physical processes, or through parameterization, but it is difficult to verify simulations. In situ observations generally measure bulk quantities. Where internal snowpack measurements are made, they tend to be destructive and unsuitable for continuous monitoring. Here, we present a novel method for in situ monitoring of water flow in seasonal snow using the electrical self-potential (SP) geophysical method. A prototype geophysical array was installed at Col de Porte (France) in October 2018. Snow hydrological and meteorological observations were also collected. Results for two periods of hydrological interest during winter 2018–19 (a marked period of diurnal melting and refreezing, and a rain-on-snow event) show that the electrical SP method is sensitive to internal water flow. Water flow was detected by SP signals before it was measured in conventional snowmelt lysimeters at the base of the snowpack. This initial feasibility study shows the utility of the SP method as a non-destructive snow sensor. Future development should include combining SP measurements with a high-resolution snow physics model to improve prediction of melt timing. [ABSTRACT FROM AUTHOR]

Published
2022
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41. An updated seabed bathymetry beneath Larsen C Ice Shelf, Antarctic Peninsula

Author

Brisbourne, Alex, Kulessa, Bernd, Hudson, Thomas, Harrison, Lianne, Holland, Paul, Luckman, Adrian, Bevan, Suzanne, Ashmore, David, Hubbard, Bryn, Pearce, Emma, White, James, Booth, Adam, Nicholls, Keith, Smith, Andrew, Brisbourne, Alex, Kulessa, Bernd, Hudson, Thomas, Harrison, Lianne, Holland, Paul, Luckman, Adrian, Bevan, Suzanne, Ashmore, David, Hubbard, Bryn, Pearce, Emma, White, James, Booth, Adam, Nicholls, Keith, and Smith, Andrew

Abstract

In recent decades, rapid ice-shelf disintegration along the Antarctic Peninsula has had a global impact through enhancing outlet glacier flow, and hence sea level rise, and the freshening of Antarctic Bottom Water. Ice shelf thinning due to basal melting results from the circulation of relatively warm water in the underlying ocean cavity. However, the effect of sub-shelf circulation on future ice-shelf stability cannot be predicted accurately with computer simulations if the geometry of the ice-shelf cavity is unknown. To address this deficit for Larsen C Ice Shelf, west Antarctica, we integrate new water-column thickness measurements with existing observations. We present these new data here along with an updated bathymetry grid of the ocean cavity. Key findings include relatively deep seabed to the south-east of the Kenyon Peninsula, along the grounding line and around the key ice shelf pinning point of Bawden Ice Rise. In addition, we can confirm that the cavity’s southern trough stretches from Mobiloil Inlet to the open ocean. These areas of deep seabed will influence ocean circulation and tidal mixing, and will therefore affect the basal-melt distribution. These results will help constrain models of ice-shelf cavity circulation with the aim of improving our understanding of sub-shelf processes and their potential influence on ice shelf stability. The data set comprises all point measurements of seabed depth and a gridded data product, derived using additional measurements of both offshore seabed depth and the thickness of grounded ice. We present all new depth measurements here as well as a compilation of previously published measurements used in the gridding process. The gridded data product is included in the supplementary material.

Published
2020

45. An updated seabed bathymetry beneath Larsen C Ice Shelf, Antarctic Peninsula

Author

Brisbourne, Alex, primary, Kulessa, Bernd, additional, Hudson, Thomas, additional, Harrison, Lianne, additional, Holland, Paul, additional, Luckman, Adrian, additional, Bevan, Suzanne, additional, Ashmore, David, additional, Hubbard, Bryn, additional, Pearce, Emma, additional, White, James, additional, Booth, Adam, additional, Nicholls, Keith, additional, and Smith, Andrew, additional

Published
2020
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47. Seismic characterization of a rapidly-rising jökulhlaup cycle at the A.P. Olsen Ice Cap, NE-Greenland

Author

Behm, Michael, primary, Walter, Jacob I., additional, Binder, Daniel, additional, Cheng, Feng, additional, Citterio, Michele, additional, Kulessa, Bernd, additional, Langley, Kirsty, additional, Limpach, Phillipe, additional, Mertl, Stefan, additional, Schöner, Wolfgang, additional, Tamstorf, Mikkel, additional, and Weyss, Gernot, additional

Published
2020
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50. Observationally constrained surface mass balance of Larsen C ice shelf, Antarctica

Author

Munneke, Peter Kuipers, McGrath, Daniel, Medley, Brooke, Luckman, Adrian, Bevan, Suzanne, Kulessa, Bernd, Jansen, Daniela, Booth, Adam, Smeets, Paul, Hubbard, Bryn, Ashmore, David, Van den Broeke, Michiel, Sevestre, Heidi, Steffen, Konrad, Shepherd, Andrew, Gourmelen, Noel, Sub Dynamics Meteorology, Marine and Atmospheric Research, Sub Dynamics Meteorology, Marine and Atmospheric Research, and University of St Andrews. School of Geography & Sustainable Development

Subjects
010504 meteorology & atmospheric sciences, 010502 geochemistry & geophysics, 01 natural sciences, Ice shelf, Glacier mass balance, G1, SDG 13 - Climate Action, lcsh:Environmental sciences, 0105 earth and related environmental sciences, Earth-Surface Processes, Water Science and Technology, lcsh:GE1-350, geography, GE, geography.geographical_feature_category, lcsh:QE1-996.5, Firn, G Geography (General), 3rd-DAS, Snow, lcsh:Geology, 13. Climate action, Climatology, Spatial ecology, Climate model, Spatial variability, Ice sheet, Geology, GE Environmental Sciences
Abstract

This work is funded by the Netherland Polar Programme, Netherlands Earth System Science Centre (NESSC), NSF OPP research grant 0732946, NERC/GEF grants NE/L006707/1, NE/L005409/1, NE/E012914/1, GEF loans 863, 890, 1028. The surface mass balance (SMB) of the Larsen C ice shelf (LCIS), Antarctica, is poorly constrained due to a dearth of in situ observations. Combining several geophysical techniques, we reconstruct spatial and temporal patterns of SMB over the LCIS. Continuous time series of snow height (2.5–6 years) at five locations allow for multi-year estimates of seasonal and annual SMB over the LCIS. There is high interannual variability in SMB as well as spatial variability: in the north, SMB is 0.40 ± 0.06 to 0.41 ± 0.04 m w.e. year−1, while farther south, SMB is up to 0.50 ± 0.05 m w.e. year−1. This difference between north and south is corroborated by winter snow accumulation derived from an airborne radar survey from 2009, which showed an average snow thickness of 0.34 m w.e. north of 66° S, and 0.40 m w.e. south of 68° S. Analysis of ground-penetrating radar from several field campaigns allows for a longer-term perspective of spatial variations in SMB: a particularly strong and coherent reflection horizon below 25–44 m of water-equivalent ice and firn is observed in radargrams collected across the shelf. We propose that this horizon was formed synchronously across the ice shelf. Combining snow height observations, ground and airborne radar, and SMB output from a regional climate model yields a gridded estimate of SMB over the LCIS. It confirms that SMB increases from north to south, overprinted by a gradient of increasing SMB to the west, modulated in the west by föhn-induced sublimation. Previous observations show a strong decrease in firn air content toward the west, which we attribute to spatial patterns of melt, refreezing, and densification rather than SMB. Publisher PDF

Published
2018

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