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4. Extensive inland thinning and speed-up of Northeast Greenland Ice Stream

Author

Khan, Shfaqat A, Choi, Youngmin, Morlighem, Mathieu, Rignot, Eric, Helm, Veit, Humbert, Angelika, Mouginot, Jérémie, Millan, Romain, Kjær, Kurt H, and Bjørk, Anders A

Subjects
Climate Action, General Science & Technology
Abstract

Over the past two decades, ice loss from the Greenland ice sheet (GrIS) has increased owing to enhanced surface melting and ice discharge to the ocean1-5. Whether continuing increased ice loss will accelerate further, and by how much, remains contentious6-9. A main contributor to future ice loss is the Northeast Greenland Ice Stream (NEGIS), Greenland's largest basin and a prominent feature of fast-flowing ice that reaches the interior of the GrIS10-12. Owing to its topographic setting, this sector is vulnerable to rapid retreat, leading to unstable conditions similar to those in the marine-based setting of ice streams in Antarctica13-20. Here we show that extensive speed-up and thinning triggered by frontal changes in 2012 have already propagated more than 200 km inland. We use unique global navigation satellite system (GNSS) observations, combined with surface elevation changes and surface speeds obtained from satellite data, to select the correct basal conditions to be used in ice flow numerical models, which we then use for future simulations. Our model results indicate that this marine-based sector alone will contribute 13.5-15.5 mm sea-level rise by 2100 (equivalent to the contribution of the entire ice sheet over the past 50 years) and will cause precipitous changes in the coming century. This study shows that measurements of subtle changes in the ice speed and elevation inland help to constrain numerical models of the future mass balance and higher-end projections show better agreement with observations.

Published
2022

5. Greenland Mass Trends From Airborne and Satellite Altimetry During 2011–2020

Author

Khan, Shfaqat A, Bamber, Jonathan L, Rignot, Eric, Helm, Veit, Aschwanden, Andy, Holland, David M, Broeke, Michiel, King, Michalea, Noël, Brice, Truffer, Martin, Humbert, Angelika, Colgan, William, Vijay, Saurabh, and Munneke, Peter Kuipers

Subjects
Earth Sciences, Physical Geography and Environmental Geoscience, Climate Action, Greenland Ice Sheet, satellite altimetry, mass loss, ice dynamics, vertical land motion, surface mass balance, Earth sciences, Environmental sciences
Abstract

We use satellite and airborne altimetry to estimate annual mass changes of the Greenland Ice Sheet. We estimate ice loss corresponding to a sea-level rise of 6.9 ± 0.4 mm from April 2011 to April 2020, with a highest annual ice loss rate of 1.4 mm/yr sea-level equivalent from April 2019 to April 2020. On a regional scale, our annual mass loss timeseries reveals 10-15 m/yr dynamic thickening at the terminus of Jakobshavn Isbræ from April 2016 to April 2018, followed by a return to dynamic thinning. We observe contrasting patterns of mass loss acceleration in different basins across the ice sheet and suggest that these spatiotemporal trends could be useful for calibrating and validating prognostic ice sheet models. In addition to resolving the spatial and temporal fingerprint of Greenland's recent ice loss, these mass loss grids are key for partitioning contemporary elastic vertical land motion from longer-term glacial isostatic adjustment (GIA) trends at GPS stations around the ice sheet. Our ice-loss product results in a significantly different GIA interpretation from a previous ice-loss product.

Published
2022

6. Ocean melting of the Zachariae Isstrøm and Nioghalvfjerdsfjorden glaciers, northeast Greenland

Author

An, Lu, Rignot, Eric, Wood, Michael, Willis, Josh K, Mouginot, Jérémie, and Khan, Shfaqat A

Subjects
Climate Action, Life Below Water, Greenland, glaciology, sea level, ice-ocean interaction, climate, ice–ocean interaction
Abstract

Zachariae Isstrøm (ZI) and Nioghalvfjerdsfjorden (79N) are marine-terminating glaciers in northeast Greenland that hold an ice volume equivalent to a 1.1-m global sea level rise. ZI lost its floating ice shelf, sped up, retreated at 650 m/y, and experienced a 5-gigaton/y mass loss. Glacier 79N has been more stable despite its exposure to the same climate forcing. We analyze the impact of ocean thermal forcing on the glaciers. A three-dimensional inversion of airborne gravity data reveals an 800-m-deep, broad channel that allows subsurface, warm, Atlantic Intermediate Water (AIW) (+1.[Formula: see text]C) to reach the front of ZI via two sills at 350-m depth. Subsurface ocean temperature in that channel has warmed by 1.3[Formula: see text]C since 1979. Using an ocean model, we calculate a rate of ice removal at the grounding line by the ocean that increased from 108 m/y to 185 m/y in 1979-2019. Observed ice thinning caused a retreat of its flotation line to increase from 105 m/y to 217 m/y, for a combined grounding line retreat of 13 km in 41 y that matches independent observations within 14%. In contrast, the limited access of AIW to 79N via a narrower passage yields lower grounded ice removal (53 m/y to 99 m/y) and thinning-induced retreat (27 m/y to 50 m/y) for a combined retreat of 4.4 km, also within 12% of observations. Ocean-induced removal of ice at the grounding line, modulated by bathymetric barriers, is therefore a main driver of ice sheet retreat, but it is not incorporated in most ice sheet models.

Published
2021

7. Centennial response of Greenland's three largest outlet glaciers.

Author

Khan, Shfaqat A, Bjørk, Anders A, Bamber, Jonathan L, Morlighem, Mathieu, Bevis, Michael, Kjær, Kurt H, Mouginot, Jérémie, Løkkegaard, Anja, Holland, David M, Aschwanden, Andy, Zhang, Bao, Helm, Veit, Korsgaard, Niels J, Colgan, William, Larsen, Nicolaj K, Liu, Lin, Hansen, Karina, Barletta, Valentina, Dahl-Jensen, Trine S, Søndergaard, Anne Sofie, Csatho, Beata M, Sasgen, Ingo, Box, Jason, and Schenk, Toni

Abstract

The Greenland Ice Sheet is the largest land ice contributor to sea level rise. This will continue in the future but at an uncertain rate and observational estimates are limited to the last few decades. Understanding the long-term glacier response to external forcing is key to improving projections. Here we use historical photographs to calculate ice loss from 1880-2012 for Jakobshavn, Helheim, and Kangerlussuaq glacier. We estimate ice loss corresponding to a sea level rise of 8.1 ± 1.1 millimetres from these three glaciers. Projections of mass loss for these glaciers, using the worst-case scenario, Representative Concentration Pathways 8.5, suggest a sea level contribution of 9.1-14.9 mm by 2100. RCP8.5 implies an additional global temperature increase of 3.7 °C by 2100, approximately four times larger than that which has taken place since 1880. We infer that projections forced by RCP8.5 underestimate glacier mass loss which could exceed this worst-case scenario.

Published
2020

8. Smoothed monthly Greenland ice sheet elevation changes during 2003–2023.

Author

Khan, Shfaqat A., Seroussi, Helene, Morlighem, Mathieu, Colgan, William, Helm, Veit, Cheng, Gong, Berg, Danjal, Barletta, Valentina R., Larsen, Nicolaj K., Kochtitzky, William, van den Broeke, Michiel, Kjær, Kurt H., Aschwanden, Andy, Noël, Brice, Box, Jason E., MacGregor, Joseph A., Fausto, Robert S., Mankoff, Kenneth D., Howat, Ian M., and Oniszk, Kuba

Subjects
*GREENLAND ice, *ICE sheets, *RADAR altimetry, *GLACIERS, *SEA level
Abstract

The surface elevation of the Greenland Ice Sheet is constantly changing due to the interplay between surface mass balance processes and ice dynamics, each exhibiting distinct spatiotemporal patterns. Here, we employ satellite and airborne altimetry data with fine spatial (1 km) and temporal (monthly) resolutions to document this spatiotemporal evolution from January 2003 to August 2023. To estimate elevation changes of the Greenland Ice Sheet (GIS), we utilize radar altimetry data from CryoSat-2 and EnviSat, laser altimetry data from the ICESat and ICESat-2, and laser altimetry data from NASA's Operation IceBridge Airborne Topographic Mapper. We produce continuous monthly ice surface elevation changes from January 2003 to August 2023 on a 1 km grid covering the entire GIS. We estimate cumulative ice loss of 4,352 Gt ± 315 Gt (12.1 ± 0.9 mm sea level equivalent) during this period, excluding peripheral glaciers. Between 2003 and 2023, the ice sheet land-terminating margin underwent a significant cumulative thinning of several meters. Ocean-terminating glaciers exhibited thinning between 20–40 m, with Jakobshavn Isbræ experiencing an exceptional thinning of nearly 70 m. This dataset of fine-resolution altimetry data in both space and time will support studies of ice mass loss and useful for GIS ice sheet modelling. To validate our monthly mass changes of the Greenland ice sheet, we use mass change from satellite gravimetry and mass change from the Input-Output method. On multiannual timescales, there is a strong correlation between the time series, with R values ranging from 0.88 to 0.92. [ABSTRACT FROM AUTHOR]

Published
2024
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10. A large impact crater beneath Hiawatha Glacier in northwest Greenland.

Author

Kjær, Kurt H, Larsen, Nicolaj K, Binder, Tobias, Bjørk, Anders A, Eisen, Olaf, Fahnestock, Mark A, Funder, Svend, Garde, Adam A, Haack, Henning, Helm, Veit, Houmark-Nielsen, Michael, Kjeldsen, Kristian K, Khan, Shfaqat A, Machguth, Horst, McDonald, Iain, Morlighem, Mathieu, Mouginot, Jérémie, Paden, John D, Waight, Tod E, Weikusat, Christian, Willerslev, Eske, and MacGregor, Joseph A

Abstract

We report the discovery of a large impact crater beneath Hiawatha Glacier in northwest Greenland. From airborne radar surveys, we identify a 31-kilometer-wide, circular bedrock depression beneath up to a kilometer of ice. This depression has an elevated rim that cross-cuts tributary subglacial channels and a subdued central uplift that appears to be actively eroding. From ground investigations of the deglaciated foreland, we identify overprinted structures within Precambrian bedrock along the ice margin that strike tangent to the subglacial rim. Glaciofluvial sediment from the largest river draining the crater contains shocked quartz and other impact-related grains. Geochemical analysis of this sediment indicates that the impactor was a fractionated iron asteroid, which must have been more than a kilometer wide to produce the identified crater. Radiostratigraphy of the ice in the crater shows that the Holocene ice is continuous and conformable, but all deeper and older ice appears to be debris rich or heavily disturbed. The age of this impact crater is presently unknown, but from our geological and geophysical evidence, we conclude that it is unlikely to predate the Pleistocene inception of the Greenland Ice Sheet.

Published
2018

12. Inland Summer Speedup at Zachariæ Isstrøm, Northeast Greenland, Driven by Subglacial Hydrology.

Author

Khan, Shfaqat A., Morlighem, Mathieu, Ehrenfeucht, Shivani, Seroussi, Helene, Choi, Youngmin, Rignot, Eric, Humbert, Angelika, Pickell, Derek, and Hassan, Javed

Subjects
*GREENLAND ice, *RUNOFF, *CLIMATE change, *HYDROLOGIC models, *GLACIERS, GLACIER speed
Abstract

The Northeast Greenland Ice Stream (NEGIS) has experienced substantial dynamic thinning in recent years. Here, we examine the evolving behavior of NEGIS, with focus on summer speedup at Zachariae Isstrøm, one of the NEGIS outlet glaciers, which has exhibited rapid retreat and acceleration, indicative of its vulnerability to changing climate conditions. Through a combination of Sentinel‐1 data, in‐situ GPS observations, and numerical ice flow modeling from 2007, we investigate the mechanisms driving short‐term changes. Our analysis reveals a summer speedup in ice flow both near the terminus and inland, with satellite data detecting changes up to 60 km inland, while GPS data capture changes up to 190 km inland along the glacier center line. We attribute this summer speedup to variations in subglacial hydrology, where surface meltwater runoff influences basal friction over the melt season. Incorporating subglacial hydrology into numerical models makes it possible to replicate observed ice velocity patterns. Plain Language Summary: The Northeast Greenland Ice Stream (NEGIS), a crucial part of the Greenland Ice Sheet, has been experiencing significant dynamic thinning recently. This study focuses on the summer speedup of Zachariae Isstrøm (ZI), one of NEGIS's outlet glaciers, which is rapidly retreating and accelerating, highlighting its sensitivity to climate change. Utilizing Sentinel‐1 satellite data, in‐situ GPS observations, and numerical ice flow modeling, we explore the mechanisms behind short‐term dynamic changes. We find that satellite data reveals short‐term summer (June to August) fluctuations in ice flow speed near the glacier terminus and up to 50–70 km inland. However, GPS data shows that this speedup extends further inland, up to at least 190 km along the main flow line. Only GPS data can detect the smaller‐scale summer speedups in these inland regions, providing critical observations for validating ice flow models. We determine that the seasonal acceleration of ice velocity at Zachariae Isstrøm is due to variations in subglacial hydrology, where surface meltwater runoff reduces basal friction by altering the subglacial hydrologic system during the melt season. Additionally, our study highlights that these findings are applicable beyond NEGIS, with similar speedup patterns observed in other Greenland glaciers. Key Points: GPS data reveal summer speed up at least 190 km inland along the main flowline of Zachariae IsstrømSubglacial hydrology is the main driver of the summer speedup near the terminus and deep inlandRecord high warming in 2019 led to a more intense and longer duration of the summer speedup [ABSTRACT FROM AUTHOR]

Published
2024
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16. GNET Derived Mass Balance and Glacial Isostatic Adjustment Constraints for Greenland

Author

Barletta, Valentina R., Bordoni, Andrea, Khan, Shfaqat Abbas, Barletta, Valentina R., Bordoni, Andrea, and Khan, Shfaqat Abbas

Abstract

Monitoring the Greenland mass balance (GMB) is crucial in the context of global sea level rise. Currently, three main methods are used to measure GMB, with the primary source of uncertainty arising from the glacial isostatic adjustment (GIA) contribution. Here, we propose a novel approach based on a simple methodology that uses the entire Greenland GNSS network (GNET) as an instrument to monitor the present-day mass changes. Our method is validated against GRACE-derived GMB, and we find a very good agreement. This leads to an independent methodology for estimating present-day mass changes from GNSS, bridging the gap between GRACE and GRACE-FO in GMB estimates. Through a combined analysis of GMB from GRACE and GNET, we identify a consistency relation between the gravity and uplift signature of GIA, providing a new robust constraint for GIA models.

Published
2024

19. Rock glacier distribution and kinematics in Shigar and Shayok basins based on radar and optical remote sensing.

Author

Hassan, Javed, Berg, Danjal Longfors, Lippert, Eigil Y. H., CHEN, Xiaoqing, Hassan, Wajid, Hassan, Muzammil, Hussain, Iqtidar, Bazai, Nazir Ahmed, and Khan, Shfaqat A.

Subjects
REMOTE sensing by radar, OPTICAL remote sensing, ROCK glaciers, GLACIER speed, SYNTHETIC aperture radar, GLOBAL warming
Abstract

Recent studies have demonstrated the rock glacier destabilisation and permafrost thawing induced by warming climate represent a continuous threat to life, infrastructure and socio‐economic development in the mountainous regions of the Hindu Kush Himalaya. This study presents the first systematic rock glacier inventory for the Shigar and Shayok basins, quantifying rock glacier geomorphology and kinematics based on morphological evidence using Google Earth images and interferometric synthetic aperture radar (InSAR). The certainty index of each inventoried rock glacier is recorded, along with its geomorphological properties and kinematic attributes. The rock glacier velocity is estimated through the InSAR time series analysis of Sentinel‐1 images from 2020 to 2021, with temporal baselines at 12‐day intervals. We developed a rock glacier inventory consisting of 84 rock glaciers covering an area of 29 km2 for the Shigar Basin and 2206 rock glaciers encompassing 369 km2 for the Shayok Basin. Among these rock glaciers, 69% and 52% are categorised as active rock glaciers, respectively. Rock glaciers in both catchments are confined to elevations between 3600 and 5875 m a.s.l., with a mean area of 0.22 km2. The maximum recorded velocity for active rock glaciers in the Shigar Basin is 101 ± 9 cm year−1, with a median of 27 ± 10 cm year−1, and in the Shayok Basin 114 ± 10 cm year−1 (median of 29 ± 9 cm year−1). Temporal variations in the surface velocities of the rock glaciers reveal that they increase with rising temperatures in both catchments, highlighting the seasonality in the rock glacier surface velocity. In total, we recorded the kinematic attributes of 98% of the inventoried rock glaciers in the study area. [ABSTRACT FROM AUTHOR]

Published
2024
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21. Spread of ice mass loss into northwest Greenland observed by GRACE and GPS

Author

Khan, Shfaqat Abbas, Wahr, John, Bevis, Michael, Velicogna, Isabella, and Kendrick, Eric

Subjects
Climate Action, Meteorology & Atmospheric Sciences
Abstract

Greenland's main outlet glaciers have more than doubled their contribution to global sea level rise over the last decade. Recent work has shown that Greenland's mass loss is still increasing. Here we show that the ice loss, which has been well-documented over southern portions of Greenland, is now spreading up along the northwest coast, with this acceleration likely starting in late 2005. We support this with two lines of evidence. One is based on measurements from the Gravity Recovery and Climate Experiment (GRACE) satellite gravity mission, launched in March 2002. The other comes from continuous Global Positioning System (GPS) measurements from three long-term sites on bedrock adjacent to the ice sheet. The GRACE results provide a direct measure of mass loss averaged over scales of a few hundred km. The GPS data are used to monitor crustal uplift caused by ice mass loss close to the sites. The GRACE results can be used to predict crustal uplift, which can be compared with the GPS data. In addition to showing that the northwest ice sheet margin is now losing mass, the uplift results from both the GPS measurements and the GRACE predictions show rapid acceleration in southeast Greenland in late 2003, followed by a moderate deceleration in 2006. Because that latter deceleration is weak, southeast Greenland still appears to be losing ice mass at a much higher rate than it was prior to fall 2003. In a more general sense, the analysis described here demonstrates that GPS uplift measurements can be used in combination with GRACE mass estimates to provide a better understanding of ongoing Greenland mass loss; an analysis approach that will become increasingly useful as long time spans of data accumulate from the 51 permanent GPS stations recently deployed around the edge of the ice sheet as part of the Greenland GPS Network (GNET). Copyright © 2010 by the American Geophysical Union.

Published
2010

22. Greenland and Canadian Arctic ice temperature profiles database

Author

Løkkegaard, Anja, primary, Mankoff, Kenneth D., additional, Zdanowicz, Christian, additional, Clow, Gary D., additional, Lüthi, Martin P., additional, Doyle, Samuel H., additional, Thomsen, Henrik H., additional, Fisher, David, additional, Harper, Joel, additional, Aschwanden, Andy, additional, Vinther, Bo M., additional, Dahl-Jensen, Dorthe, additional, Zekollari, Harry, additional, Meierbachtol, Toby, additional, McDowell, Ian, additional, Humphrey, Neil, additional, Solgaard, Anne, additional, Karlsson, Nanna B., additional, Khan, Shfaqat A., additional, Hills, Benjamin, additional, Law, Robert, additional, Hubbard, Bryn, additional, Christoffersen, Poul, additional, Jacquemart, Mylène, additional, Seguinot, Julien, additional, Fausto, Robert S., additional, and Colgan, William T., additional

Published
2023
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23. Precursor of disintegration of Greenland's largest floating ice tongue

Author

Humbert, Angelika, primary, Helm, Veit, additional, Neckel, Niklas, additional, Zeising, Ole, additional, Rückamp, Martin, additional, Khan, Shfaqat Abbas, additional, Loebel, Erik, additional, Brauchle, Jörg, additional, Stebner, Karsten, additional, Gross, Dietmar, additional, Sondershaus, Rabea, additional, and Müller, Ralf, additional

Published
2023
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25. Precursor of disintegration of Greenland's largest floating ice tongue

Author

Humbert, Angelika, Helm, Veit, Neckel, Niklas, Zeising, Ole, Rückamp, Martin, Khan, Shfaqat Abbas, Loebel, Erik, Brauchle, Jörg, Stebner, Karsten, Gross, Dietmar, Sondershaus, Rabea, and Müller, Ralf

Abstract

The largest floating tongue of Greenland’s ice sheet, Nioghalvfjerdsbræ, has been relatively stable with respect to areal retreat until 2022. Draining more than 6 % of the ice sheet, a disintegration of Nioghalvfjerdsbræ's floating tongue and subsequent acceleration due to loss in buttressing are likely to lead to sea level rise. Therefore, the stability of the floating tongue is a focus of this study. We employed a suite of observational methods to detect recent changes at the calving front. We found that the calving style has changed since 2016 at the southern part of the eastern calving front, from tongue-type calving to a crack evolution initiated at frontal ice rises reaching 5–7 km and progressing further upstream compared to 2010. The calving front area is further weakened by an area upstream of the main calving front that consists of open water and an ice mélange that has substantially expanded, leading to the formation of a narrow ice bridge. These geometric and mechanical changes may be a precursor of instability of the floating tongue. We complement our study by numerical ice flow simulations to estimate the impact of future ice-front retreat and complete ice shelf disintegration on the discharge of grounded ice. These idealized scenarios reveal that a loss of the south-eastern area of the ice shelf would lead to a 0.2 % increase in ice discharge at the grounding line, while a sudden collapse of the frontal area (46 % of the floating tongue area) will enhance the ice discharge by 5.1 % due to loss in buttressing. Eventually, a full collapse of the floating tongue increases the grounding line flux by 166 %.

Published
2023

26. Mass balance of the Greenland and Antarctic ice sheets from 1992 to 2020

Author

Otosaka, Inès N., Shepherd, Andrew, Ivins, Erik R., Schlegel, Nicole Jeanne, Amory, Charles, Van Den Broeke, Michiel R., Horwath, Martin, Joughin, Ian, King, Michalea D., Krinner, Gerhard, Nowicki, Sophie, Payne, Anthony J., Rignot, Eric, Scambos, Ted, Simon, Karen M., Smith, Benjamin E., Sørensen, Louise S., Velicogna, Isabella, Whitehouse, Pippa L., Geruo, A., Agosta, Cécile, Ahlstrøm, Andreas P., Blazquez, Alejandro, Colgan, William, Engdahl, Marcus E., Fettweis, Xavier, Forsberg, Rene, Gallée, Hubert, Gardner, Alex, Gilbert, Lin, Gourmelen, Noel, Groh, Andreas, Gunter, Brian C., Harig, Christopher, Helm, Veit, Khan, Shfaqat Abbas, Kittel, Christoph, Konrad, Hannes, Langen, Peter L., Lecavalier, Benoit S., Liang, Chia Chun, Loomis, Bryant D., McMillan, Malcolm, Melini, Daniele, Mernild, Sebastian H., Mottram, Ruth, Mouginot, Jeremie, Nilsson, Johan, Noël, Brice, Pattle, Mark E., Peltier, William R., Pie, Nadege, Roca, Mònica, Sasgen, Ingo, Save, Himanshu V., Seo, Ki Weon, Scheuchl, Bernd, Schrama, Ernst J.O., Schröder, Ludwig, Simonsen, Sebastian B., Slater, Thomas, Spada, Giorgio, Sutterley, Tyler C., Vishwakarma, Bramha Dutt, Van Wessem, Jan Melchior, Wiese, David, Van Der Wal, Wouter, Wouters, Bert, Otosaka, Inès N., Shepherd, Andrew, Ivins, Erik R., Schlegel, Nicole Jeanne, Amory, Charles, Van Den Broeke, Michiel R., Horwath, Martin, Joughin, Ian, King, Michalea D., Krinner, Gerhard, Nowicki, Sophie, Payne, Anthony J., Rignot, Eric, Scambos, Ted, Simon, Karen M., Smith, Benjamin E., Sørensen, Louise S., Velicogna, Isabella, Whitehouse, Pippa L., Geruo, A., Agosta, Cécile, Ahlstrøm, Andreas P., Blazquez, Alejandro, Colgan, William, Engdahl, Marcus E., Fettweis, Xavier, Forsberg, Rene, Gallée, Hubert, Gardner, Alex, Gilbert, Lin, Gourmelen, Noel, Groh, Andreas, Gunter, Brian C., Harig, Christopher, Helm, Veit, Khan, Shfaqat Abbas, Kittel, Christoph, Konrad, Hannes, Langen, Peter L., Lecavalier, Benoit S., Liang, Chia Chun, Loomis, Bryant D., McMillan, Malcolm, Melini, Daniele, Mernild, Sebastian H., Mottram, Ruth, Mouginot, Jeremie, Nilsson, Johan, Noël, Brice, Pattle, Mark E., Peltier, William R., Pie, Nadege, Roca, Mònica, Sasgen, Ingo, Save, Himanshu V., Seo, Ki Weon, Scheuchl, Bernd, Schrama, Ernst J.O., Schröder, Ludwig, Simonsen, Sebastian B., Slater, Thomas, Spada, Giorgio, Sutterley, Tyler C., Vishwakarma, Bramha Dutt, Van Wessem, Jan Melchior, Wiese, David, Van Der Wal, Wouter, and Wouters, Bert

Abstract

Ice losses from the Greenland and Antarctic ice sheets have accelerated since the 1990s, accounting for a significant increase in the global mean sea level. Here, we present a new 29-year record of ice sheet mass balance from 1992 to 2020 from the Ice Sheet Mass Balance Inter-comparison Exercise (IMBIE). We compare and combine 50 independent estimates of ice sheet mass balance derived from satellite observations of temporal changes in ice sheet flow, in ice sheet volume, and in Earth's gravity field. Between 1992 and 2020, the ice sheets contributed 21.0±1.9g€¯mm to global mean sea level, with the rate of mass loss rising from 105g€¯Gtg€¯yr-1 between 1992 and 1996 to 372g€¯Gtg€¯yr-1 between 2016 and 2020. In Greenland, the rate of mass loss is 169±9g€¯Gtg€¯yr-1 between 1992 and 2020, but there are large inter-annual variations in mass balance, with mass loss ranging from 86g€¯Gtg€¯yr-1 in 2017 to 444g€¯Gtg€¯yr-1 in 2019 due to large variability in surface mass balance. In Antarctica, ice losses continue to be dominated by mass loss from West Antarctica (82±9g€¯Gtg€¯yr-1) and, to a lesser extent, from the Antarctic Peninsula (13±5g€¯Gtg€¯yr-1). East Antarctica remains close to a state of balance, with a small gain of 3±15g€¯Gtg€¯yr-1, but is the most uncertain component of Antarctica's mass balance. The dataset is publicly available at 10.5285/77B64C55-7166-4A06-9DEF-2E400398E452 (IMBIE Team, 2021).

Published
2023

27. Greenland and Canadian Arctic ice temperature profiles database

Author

Løkkegaard, Anja, Mankoff, Kenneth D., Zdanowicz, Christian, Clow, Gary D., Lüthi, Martin P., Doyle, Samuel H., Thomsen, Henrik H., Fisher, David, Harper, Joel, Aschwanden, Andy, Vinther, Bo M., Dahl-Jensen, Dorthe, Zekollari, Harry, Meierbachtol, Toby, McDowell, Ian, Humphrey, Neil, Solgaard, Anne, Karlsson, Nanna B., Khan, Shfaqat A., Hills, Benjamin, Law, Robert, Hubbard, Bryn, Christoffersen, Poul, Jacquemart, Mylène, Seguinot, Julien, Fausto, Robert S., Colgan, William T., Løkkegaard, Anja, Mankoff, Kenneth D., Zdanowicz, Christian, Clow, Gary D., Lüthi, Martin P., Doyle, Samuel H., Thomsen, Henrik H., Fisher, David, Harper, Joel, Aschwanden, Andy, Vinther, Bo M., Dahl-Jensen, Dorthe, Zekollari, Harry, Meierbachtol, Toby, McDowell, Ian, Humphrey, Neil, Solgaard, Anne, Karlsson, Nanna B., Khan, Shfaqat A., Hills, Benjamin, Law, Robert, Hubbard, Bryn, Christoffersen, Poul, Jacquemart, Mylène, Seguinot, Julien, Fausto, Robert S., and Colgan, William T.

Abstract

Here, we present a compilation of 95 ice temperature profiles from 85 boreholes from the Greenland ice sheet and peripheral ice caps, as well as local ice caps in the Canadian Arctic. Profiles from only 31 boreholes (36 %) were previously available in open-access data repositories. The remaining 54 borehole profiles (64 %) are being made digitally available here for the first time. These newly available profiles, which are associated with pre-2010 boreholes, have been submitted by community members or digitized from published graphics and/or data tables. All 95 profiles are now made available in both absolute (meters) and normalized (0 to 1 ice thickness) depth scales and are accompanied by extensive metadata. These metadata include a transparent description of data provenance. The ice temperature profiles span 70 years, with the earliest profile being from 1950 at Camp VI, West Greenland. To highlight the value of this database in evaluating ice flow simulations, we compare the ice temperature profiles from the Greenland ice sheet with an ice flow simulation by the Parallel Ice Sheet Model (PISM). We find a cold bias in modeled near-surface ice temperatures within the ablation area, a warm bias in modeled basal ice temperatures at inland cold-bedded sites, and an apparent underestimation of deformational heating in high-strain settings. These biases provide process level insight on simulated ice temperatures.

Published
2023
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28. Closing Greenland's Mass Balance:Frontal Ablation of Every Greenlandic Glacier From 2000 to 2020

Author

Kochtitzky, William, Copland, Luke, King, Michalea, Hugonnet, Romain, Jiskoot, Hester, Morlighem, Mathieu, Millan, Romain, Khan, Shfaqat Abbas, Noël, Brice, Kochtitzky, William, Copland, Luke, King, Michalea, Hugonnet, Romain, Jiskoot, Hester, Morlighem, Mathieu, Millan, Romain, Khan, Shfaqat Abbas, and Noël, Brice

Abstract

In Greenland, 87% of the glacierized area terminates in the ocean, but mass lost at the ice-ocean interface, or frontal ablation, has not yet been fully quantified. Using measurements and models we calculate frontal ablation of Greenland's 213 outlet and 537 peripheral glaciers and find a total frontal ablation of 481.8 ± 24.0 for 2000–2010 and 510.2 ± 18.6 Gt a−1 for 2010–2020. Ice discharge accounted for ∼90% of frontal ablation during both periods, while mass loss due to terminus retreat comprised the remainder. Only 16 glaciers were responsible for the majority (>50%) of frontal ablation from 2010 to 2020. These estimates, along with the climatic-basal balance, allow for a more complete accounting of Greenland Ice Sheet and peripheral glacier mass balance. In total, Greenland accounted for ∼90% of Northern Hemisphere frontal ablation for 2000–2010 and 2010–2020.

Published
2023

29. Sixty years of ice form and flow at Camp Century, Greenland

Author

Colgan, William, Jakobsen, Jakob, Solgaard, Anne, Lokkegaard, Anja, Abermann, Jakob, Khan, Shfaqat A., Csatho, Beata, MacGregor, Joseph A., Fausto, Robert S., Karlsson, Nanna, Pedersen, Allan O., Andersen, Signe B., Sonntag, John, Hvidberg, Christine S., Ahlstrom, Andreas P., Colgan, William, Jakobsen, Jakob, Solgaard, Anne, Lokkegaard, Anja, Abermann, Jakob, Khan, Shfaqat A., Csatho, Beata, MacGregor, Joseph A., Fausto, Robert S., Karlsson, Nanna, Pedersen, Allan O., Andersen, Signe B., Sonntag, John, Hvidberg, Christine S., and Ahlstrom, Andreas P.

Abstract

The magnitude and azimuth of horizontal ice flow at Camp Century, Greenland have been measured several times since 1963. Here, we provide a further two independent measurements over the 2017–21 period. Our consensus estimate of horizontal ice flow from four independent satellite-positioning solutions is 3.65 ± 0.13 m a−1 at an azimuth of 236 ± 2°. A portion of the small, but significant, differences in ice velocity and azimuth reported between studies likely results from spatial gradients in ice flow. This highlights the importance of restricting inter-study comparisons of ice flow estimates to measurements surveyed within a horizontal distance of one ice thickness from each other. We suggest that ice flow at Camp Century is stable on seasonal to multi-decadal timescales. The airborne and satellite laser altimetry record indicates an ice thickening trend of 1.1 ± 0.3 cm a−1 since 1994. This thickening trend is qualitatively consistent with previously inferred ongoing millennial-scale ice thickening at Camp Century. The ice flow divide immediately north of Camp Century may now be migrating southward, although the reasons for this divide migration are poorly understood. The Camp Century flowlines presently terminate in the vicinity of Innaqqissorsuup Oqquani Sermeq (Gade Gletsjer) on the Melville Bay coast.

Published
2023

30. Recent changes in drainage route and outburst magnitude of the Russell Glacier ice-dammed lake, West Greenland

Author

Dømgaard, Mads, Kjeldsen, Kristian K., Huiban, Flora, Carrivick, Jonathan L., Khan, Shfaqat A., Bjørk, Anders A., Dømgaard, Mads, Kjeldsen, Kristian K., Huiban, Flora, Carrivick, Jonathan L., Khan, Shfaqat A., and Bjørk, Anders A.

Abstract

Glacial lake outburst floods (GLOFs) or jökulhlaups from ice-dammed lakes are frequent in Greenland and can influence local ice dynamics and bedrock motion, cause geomorphological changes, and pose flooding hazards. Multidecadal time series of lake drainage dates, volumes, and flood outlets are extremely rare. However, they are essential for determining the scale and frequency of future GLOFs, for identifying drainage mechanisms, and for mitigating downstream flood effects. In this study, we use high-resolution digital elevation models (DEMs) and orthophotos (0.1×0.1m) generated from uncrewed-aerial-vehicle (UAV) field surveys, in combination with optical satellite imagery. This allows us to reconstruct robust lake volume changes associated with 14 GLOFs between 2007 and 2021 at Russell Glacier, West Greenland. As a result, this is one of the most comprehensive and longest records of ice-dammed lake drainages in Greenland to date. Importantly, we find a mean difference of ∼10% between our lake drainage volumes when compared with estimates derived from a gauged hydrograph 27km downstream. Due to thinning of the local ice dam, the potential maximum drainage volume in 2021 is ∼60% smaller than that estimated to have drained in 2007. Our time series also reveals variations in the drainage dates ranging from late May to mid-September and drainage volumes ranging between 0.9 and 37.7Mm3. We attribute these fluctuations between short periods of relatively high and low drainage volumes to a weakening of the ice dam and an incomplete sealing of the englacial tunnel following the large GLOFs. This syphoning drainage mechanism is triggered by a reduction in englacial meltwater, likely driven by late-season drainage and sudden air temperature reductions, as well as annual variations in the glacial drainage system. Furthermore, we provide geomorphological evidence of an additional drainage route first observed following the 2021 GLOF, with a subglacial or englacial flo

Published
2023

31. Satellite Magnetics Suggest a Complex Geothermal Heat Flux Pattern beneath the Greenland Ice Sheet

Author

Kolster, Mick Emil, Døssing, Arne, Khan, Shfaqat Abbas, Kolster, Mick Emil, Døssing, Arne, and Khan, Shfaqat Abbas

Abstract

Geothermal heat flow is key to unraveling several large-scale geophysical systems, including the inner workings of the Greenlandic ice sheet, and by extension, the possibility of understanding the past and prior global climate. Similarly, it could provide insight into the paleo-trace of the Icelandic mantle plume, which in turn is integral in answering long-standing questions on the origin of mountains in western and eastern Greenland and in Norway. This study documents the results from an intra-scientific field approach, which combines geological, petrophysical, and satellite magnetic field data in a nonlinear probabilistic inversion. These results include Curie depths with associated uncertainties and Geothermal Heat Flux estimates. While baselines remain challenging to evaluate due to the strong nonlinearity of the problem posed, stress testing reveals a high robustness of the predicted spatial variations, which largely disagree with the classic straightforward northwest–southeast or east–west plume trace across Greenland. Instead, our results indicate a complex heat flux pattern, including a localized region with anomalously heightened heat flux near the origin of the Northeast Greenland Ice Stream.

Published
2023

32. Mass balance of the Greenland and Antarctic ice sheets from 1992 to 2020

Author

Sub Dynamics Meteorology, Structural geology and EM, Marine and Atmospheric Research, Otosaka, Inès N., Shepherd, Andrew, Ivins, Erik R., Schlegel, Nicole Jeanne, Amory, Charles, Van Den Broeke, Michiel R., Horwath, Martin, Joughin, Ian, King, Michalea D., Krinner, Gerhard, Nowicki, Sophie, Payne, Anthony J., Rignot, Eric, Scambos, Ted, Simon, Karen M., Smith, Benjamin E., Sørensen, Louise S., Velicogna, Isabella, Whitehouse, Pippa L., Geruo, A., Agosta, Cécile, Ahlstrøm, Andreas P., Blazquez, Alejandro, Colgan, William, Engdahl, Marcus E., Fettweis, Xavier, Forsberg, Rene, Gallée, Hubert, Gardner, Alex, Gilbert, Lin, Gourmelen, Noel, Groh, Andreas, Gunter, Brian C., Harig, Christopher, Helm, Veit, Khan, Shfaqat Abbas, Kittel, Christoph, Konrad, Hannes, Langen, Peter L., Lecavalier, Benoit S., Liang, Chia Chun, Loomis, Bryant D., McMillan, Malcolm, Melini, Daniele, Mernild, Sebastian H., Mottram, Ruth, Mouginot, Jeremie, Nilsson, Johan, Noël, Brice, Pattle, Mark E., Peltier, William R., Pie, Nadege, Roca, Mònica, Sasgen, Ingo, Save, Himanshu V., Seo, Ki Weon, Scheuchl, Bernd, Schrama, Ernst J.O., Schröder, Ludwig, Simonsen, Sebastian B., Slater, Thomas, Spada, Giorgio, Sutterley, Tyler C., Vishwakarma, Bramha Dutt, Van Wessem, Jan Melchior, Wiese, David, Van Der Wal, Wouter, Wouters, Bert, Sub Dynamics Meteorology, Structural geology and EM, Marine and Atmospheric Research, Otosaka, Inès N., Shepherd, Andrew, Ivins, Erik R., Schlegel, Nicole Jeanne, Amory, Charles, Van Den Broeke, Michiel R., Horwath, Martin, Joughin, Ian, King, Michalea D., Krinner, Gerhard, Nowicki, Sophie, Payne, Anthony J., Rignot, Eric, Scambos, Ted, Simon, Karen M., Smith, Benjamin E., Sørensen, Louise S., Velicogna, Isabella, Whitehouse, Pippa L., Geruo, A., Agosta, Cécile, Ahlstrøm, Andreas P., Blazquez, Alejandro, Colgan, William, Engdahl, Marcus E., Fettweis, Xavier, Forsberg, Rene, Gallée, Hubert, Gardner, Alex, Gilbert, Lin, Gourmelen, Noel, Groh, Andreas, Gunter, Brian C., Harig, Christopher, Helm, Veit, Khan, Shfaqat Abbas, Kittel, Christoph, Konrad, Hannes, Langen, Peter L., Lecavalier, Benoit S., Liang, Chia Chun, Loomis, Bryant D., McMillan, Malcolm, Melini, Daniele, Mernild, Sebastian H., Mottram, Ruth, Mouginot, Jeremie, Nilsson, Johan, Noël, Brice, Pattle, Mark E., Peltier, William R., Pie, Nadege, Roca, Mònica, Sasgen, Ingo, Save, Himanshu V., Seo, Ki Weon, Scheuchl, Bernd, Schrama, Ernst J.O., Schröder, Ludwig, Simonsen, Sebastian B., Slater, Thomas, Spada, Giorgio, Sutterley, Tyler C., Vishwakarma, Bramha Dutt, Van Wessem, Jan Melchior, Wiese, David, Van Der Wal, Wouter, and Wouters, Bert

Published
2023

33. Greenland and Canadian Arctic ice temperature profiles database

Author

Løkkegaard, Anja; https://orcid.org/0000-0002-1947-5773, Mankoff, Kenneth D; https://orcid.org/0000-0001-5453-2019, Zdanowicz, Christian; https://orcid.org/0000-0002-1045-5063, Clow, Gary D; https://orcid.org/0000-0002-2262-3853, Lüthi, Martin P; https://orcid.org/0000-0003-4419-8496, Doyle, Samuel H; https://orcid.org/0000-0002-0853-431X, Thomsen, Henrik H, Fisher, David, Harper, Joel; https://orcid.org/0000-0002-2151-8509, Aschwanden, Andy; https://orcid.org/0000-0001-8149-2315, Vinther, Bo M, Dahl-Jensen, Dorthe, Zekollari, Harry; https://orcid.org/0000-0002-7443-4034, Meierbachtol, Toby, McDowell, Ian; https://orcid.org/0000-0003-1285-724X, Humphrey, Neil, Solgaard, Anne; https://orcid.org/0000-0002-8693-620X, Karlsson, Nanna B; https://orcid.org/0000-0003-0423-8705, Khan, Shfaqat A; https://orcid.org/0000-0002-2689-8563, Hills, Benjamin; https://orcid.org/0000-0003-4490-7416, Law, Robert; https://orcid.org/0000-0003-0067-5537, Hubbard, Bryn; https://orcid.org/0000-0002-3565-3875, Christoffersen, Poul; https://orcid.org/0000-0003-2643-8724, Jacquemart, Mylène; https://orcid.org/0000-0003-2501-7645, Seguinot, Julien; https://orcid.org/0000-0002-5315-0761, Fausto, Robert S; https://orcid.org/0000-0003-1317-8185, Colgan, William T; https://orcid.org/0000-0001-6334-1660, Løkkegaard, Anja; https://orcid.org/0000-0002-1947-5773, Mankoff, Kenneth D; https://orcid.org/0000-0001-5453-2019, Zdanowicz, Christian; https://orcid.org/0000-0002-1045-5063, Clow, Gary D; https://orcid.org/0000-0002-2262-3853, Lüthi, Martin P; https://orcid.org/0000-0003-4419-8496, Doyle, Samuel H; https://orcid.org/0000-0002-0853-431X, Thomsen, Henrik H, Fisher, David, Harper, Joel; https://orcid.org/0000-0002-2151-8509, Aschwanden, Andy; https://orcid.org/0000-0001-8149-2315, Vinther, Bo M, Dahl-Jensen, Dorthe, Zekollari, Harry; https://orcid.org/0000-0002-7443-4034, Meierbachtol, Toby, McDowell, Ian; https://orcid.org/0000-0003-1285-724X, Humphrey, Neil, Solgaard, Anne; https://orcid.org/0000-0002-8693-620X, Karlsson, Nanna B; https://orcid.org/0000-0003-0423-8705, Khan, Shfaqat A; https://orcid.org/0000-0002-2689-8563, Hills, Benjamin; https://orcid.org/0000-0003-4490-7416, Law, Robert; https://orcid.org/0000-0003-0067-5537, Hubbard, Bryn; https://orcid.org/0000-0002-3565-3875, Christoffersen, Poul; https://orcid.org/0000-0003-2643-8724, Jacquemart, Mylène; https://orcid.org/0000-0003-2501-7645, Seguinot, Julien; https://orcid.org/0000-0002-5315-0761, Fausto, Robert S; https://orcid.org/0000-0003-1317-8185, and Colgan, William T; https://orcid.org/0000-0001-6334-1660

Abstract

Here, we present a compilation of 95 ice temperature profiles from 85 boreholes from the Greenland ice sheet and peripheral ice caps, as well as local ice caps in the Canadian Arctic. Profiles from only 31 boreholes (36 %) were previously available in open-access data repositories. The remaining 54 borehole profiles (64 %) are being made digitally available here for the first time. These newly available profiles, which are associated with pre-2010 boreholes, have been submitted by community members or digitized from published graphics and/or data tables. All 95 profiles are now made available in both absolute (meters) and normalized (0 to 1 ice thickness) depth scales and are accompanied by extensive metadata. These metadata include a transparent description of data provenance. The ice temperature profiles span 70 years, with the earliest profile being from 1950 at Camp VI, West Greenland. To highlight the value of this database in evaluating ice flow simulations, we compare the ice temperature profiles from the Greenland ice sheet with an ice flow simulation by the Parallel Ice Sheet Model (PISM). We find a cold bias in modeled near-surface ice temperatures within the ablation area, a warm bias in modeled basal ice temperatures at inland cold-bedded sites, and an apparent underestimation of deformational heating in high-strain settings. These biases provide process level insight on simulated ice temperatures.

Published
2023

35. Mass balance of the Greenland and Antarctic ice sheets from 1992 to 2020

Author

Otosaka, Inès N., primary, Shepherd, Andrew, additional, Ivins, Erik R., additional, Schlegel, Nicole-Jeanne, additional, Amory, Charles, additional, van den Broeke, Michiel R., additional, Horwath, Martin, additional, Joughin, Ian, additional, King, Michalea D., additional, Krinner, Gerhard, additional, Nowicki, Sophie, additional, Payne, Anthony J., additional, Rignot, Eric, additional, Scambos, Ted, additional, Simon, Karen M., additional, Smith, Benjamin E., additional, Sørensen, Louise S., additional, Velicogna, Isabella, additional, Whitehouse, Pippa L., additional, A, Geruo, additional, Agosta, Cécile, additional, Ahlstrøm, Andreas P., additional, Blazquez, Alejandro, additional, Colgan, William, additional, Engdahl, Marcus E., additional, Fettweis, Xavier, additional, Forsberg, Rene, additional, Gallée, Hubert, additional, Gardner, Alex, additional, Gilbert, Lin, additional, Gourmelen, Noel, additional, Groh, Andreas, additional, Gunter, Brian C., additional, Harig, Christopher, additional, Helm, Veit, additional, Khan, Shfaqat Abbas, additional, Kittel, Christoph, additional, Konrad, Hannes, additional, Langen, Peter L., additional, Lecavalier, Benoit S., additional, Liang, Chia-Chun, additional, Loomis, Bryant D., additional, McMillan, Malcolm, additional, Melini, Daniele, additional, Mernild, Sebastian H., additional, Mottram, Ruth, additional, Mouginot, Jeremie, additional, Nilsson, Johan, additional, Noël, Brice, additional, Pattle, Mark E., additional, Peltier, William R., additional, Pie, Nadege, additional, Roca, Mònica, additional, Sasgen, Ingo, additional, Save, Himanshu V., additional, Seo, Ki-Weon, additional, Scheuchl, Bernd, additional, Schrama, Ernst J. O., additional, Schröder, Ludwig, additional, Simonsen, Sebastian B., additional, Slater, Thomas, additional, Spada, Giorgio, additional, Sutterley, Tyler C., additional, Vishwakarma, Bramha Dutt, additional, van Wessem, Jan Melchior, additional, Wiese, David, additional, van der Wal, Wouter, additional, and Wouters, Bert, additional

Published
2023
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41. Delta progradation in Greenland driven by increasing glacial mass loss

Author

Bendixen, Mette, Lnsmann Iversen, Lars, Anker Bjrk, Anders, Elberling, Bo, Westergaard-Nielsen, Andreas, Overeem, Irina, Barnhart, Katy R., Abbas Khan, Shfaqat, Box, Jason E., Abermann, Jakob, Langley, Kirsty, and Kroon, Aart

Subjects
Glaciers -- Environmental aspects, Surface-ice melting -- Environmental aspects, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Author(s): Mette Bendixen (corresponding author) [1]; Lars Lnsmann Iversen [2]; Anders Anker Bjrk [3, 4, 5]; Bo Elberling [1]; Andreas Westergaard-Nielsen [1]; Irina Overeem [6]; Katy R. Barnhart [7]; Shfaqat [...]

Published
2017
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43. High-resolution modeling of dynamic vertical land movement in the Northern Hemisphere due to changing ice sheets and glaciers

Author

Ludwigsen, Carsten, Andersen, Ole, and Khan, Shfaqat Abbas

Abstract

The impact of elastic vertical land movement (VLM) on relative sea levels along the world's coastlines is significant. In Northern Europe, VLM is mainly due to the effect of Glacial Isostatic Adjustment (GIA). However, the rapid melting of ice in the Arctic is causing a substantial elastic uplift with both a local, but also a long-range footprint of 1000-3000 km from the point of ice loss. When VLM estimates from GNSS are unavailable, sea-level studies based on tide gauges often rely on a GIA-only VLM model to correct any ongoing uplift, but in Arctic regions, this can lead to underestimation of the uplift or overestimation of the absolute sea-level change due to significant changes in present-day ice loading (PDIL).Here, a high-resolution time-varying elastic VLM model (5x5 km) is developed from high-resolution estimates of glacial and Greenland Ice Sheet mass balance is presented. The elastic VLM model is combined with a GIA model to create a complete VLM model that is comparable with GNSS-measured VLM rates (in a center of mass frame). Additionally, far-field elastic effects from the Antarctic and Terrestrial Water Storage are included to create a complete vertical deformation map for the Northern Hemisphere, that can complement sea level studies in areas with few or no GNSS measurements., The 28th IUGG General Assembly (IUGG2023) (Berlin 2023)

Published
2023

44. Sixty years of ice form and flow at Camp Century, Greenland

Author

Colgan, William, primary, Jakobsen, Jakob, additional, Solgaard, Anne, additional, Løkkegaard, Anja, additional, Abermann, Jakob, additional, Khan, Shfaqat A., additional, Csatho, Beata, additional, MacGregor, Joseph A., additional, Fausto, Robert S., additional, Karlsson, Nanna, additional, Pedersen, Allan Ø., additional, Andersen, Signe B., additional, Sonntag, John, additional, Hvidberg, Christine S., additional, and Ahlstrøm, Andreas P., additional

Published
2022
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45. Closing Greenland's Mass Balance: Frontal Ablation of Every Greenlandic Glacier From 2000 to 2020.

Author

Kochtitzky, William, Copland, Luke, King, Michalea, Hugonnet, Romain, Jiskoot, Hester, Morlighem, Mathieu, Millan, Romain, Khan, Shfaqat Abbas, and Noël, Brice

Subjects
GLACIERS, GREENLAND ice, ICE sheets
Abstract

In Greenland, 87% of the glacierized area terminates in the ocean, but mass lost at the ice‐ocean interface, or frontal ablation, has not yet been fully quantified. Using measurements and models we calculate frontal ablation of Greenland's 213 outlet and 537 peripheral glaciers and find a total frontal ablation of 481.8 ± 24.0 for 2000–2010 and 510.2 ± 18.6 Gt a−1 for 2010–2020. Ice discharge accounted for ∼90% of frontal ablation during both periods, while mass loss due to terminus retreat comprised the remainder. Only 16 glaciers were responsible for the majority (>50%) of frontal ablation from 2010 to 2020. These estimates, along with the climatic‐basal balance, allow for a more complete accounting of Greenland Ice Sheet and peripheral glacier mass balance. In total, Greenland accounted for ∼90% of Northern Hemisphere frontal ablation for 2000–2010 and 2010–2020. Plain Language Summary: We estimate the mass of ice lost from all Greenland glaciers that entered the ocean during each of the last two decades. This ice loss at the front of these marine‐terminating glaciers is called frontal ablation and is approximately equal to the mass of icebergs entering the ocean. Frontal ablation is important because 87% of glacier area in Greenland ends in the ocean, through 750 outlets, and previous work has only approximated frontal ablation. This study quantifies it for the first time, helping to close the mass budget for the Greenland Ice Sheet and better partition its mass balance into components. We find that Greenland accounts for ∼90% of all Northern Hemisphere frontal ablation and, of that contribution, just 17 glaciers for 2000–2010 and 16 glaciers for 2010–2020 account for more than half of total Greenland frontal ablation. Key Points: Frontal ablation of the Greenland Ice Sheet averaged 510.2 ± 18.6 Gt a−1 for 2010–2020, ∼90% of which came from ice dischargeThe frontal ablation we measured is larger than the total mass loss from the ice sheet, indicating a positive climatic‐basal balanceOnly 16 glaciers account for 50% of the total frontal ablation from the Greenland Ice Sheet [ABSTRACT FROM AUTHOR]

Published
2023
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46. Precursor of disintegration of Greenland's largest floating ice tongue

Author

Angelika Humbert, Veit Helm, Niklas Neckel, Ole Zeising, Martin Rückamp, Khan Shfaqat Abbas, Loebel Erik, Dietmar Gross, Rabea Sondershaus, and Ralf Müller

Abstract

The largest floating tongue of Greenland’s ice sheet, Nioghalvfjerdsbrae, has so far been relatively stable with respect to areal retreat. Curiously, it experienced significant less thinning and ice flow acceleration than its neighbour Zacharias Isbrae. Draining more than 6% of the ice sheet, Nioghalvfjerdsbrae might become a large contributor to sea level rise in the future. Therefore, the stability of the floating tongue is a focus of this study. We employ a suite of observational methods to detect recent changes. We found that the calving style has changed at the southern part of the eastern calving front from normal tongue-type calving to a crack evolution initiated at frontal ice rises reaching 5-7km and progressing further upstream compared to 2010. The calving front area is further weakened by a substantial increase of a zone of fragments and open water at the tongue’s southern margin, leading to the formation of a narrow ice bridge. These geometric and mechanical changes are a precursor of instability of the floating tongue. We complement our study by numerical ice flow simulations to estimate the impact of future break-up or disintegration events on the ice discharge. These idealised scenarios reveal that a loss of the south-eastern area would lead to 1% of increase of ice discharge at the grounding line, while a sudden collapse of the frontal area (46% of the floating tongue area) will enhance the ice discharge by 8.3% due to loss in buttressing.Humbert, A., Helm, V., Neckel, N., Zeising, O., Rückamp, M., Khan, S. A., Loebel, E., Gross, D., Sondershaus, R., and Müller, R.: Precursor of disintegration of Greenland's largest floating ice tongue, The Cryosphere Discuss. [preprint], https://doi.org/10.5194/tc-2022-171, in review, 2022

Published
2022
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47. Deliverable 6.19 Synthesis report from WP6: Application studies of Arctic Observing Systems towards stakeholders

Author

Ottersen, Geir, Sejr, Mikael K., Döscher, Ralf, Goeckede, Mathias, Iversen, Lisbeth, Kruschke, Tim, Maar, Marie, van der Meeren, Gro I., Sagen, Hanne, Solgaard, Anne M., Ahlstrøm, Andreas Peter, Andersen, Ole B., Ardhuin, Fanny, Beszczynska-Möller, Agnieszka, Buch, Erik, Christensen, Asbjørn, Caumont, Hervé, Cheng, Bin, Danielsen, Finn, de Andrés, Eva, de Corcuera, María Isabel, Enghoff, Martin, Geyer, Florian, Grynczel, Agata, Gustafsson, David, Hamre, Torill, Hancock, Holt, Hansen, Cecilie, Heygster, Georg, Hu, Siwei, Istomina, Larysa, Johannessen, Truls, Juul-Pedersen, Thomas, King, Andrew, Khan, Shfaqat Abbas, Köhl, Armin, Larsen, Janus, Lei, Ruibo, Ludwigsen, Carsten B., Lygre, Kjetil, Lyu, Guokun, Mankoff, Kenneth, Melsheimer, Christian, Monsen, Frode, Møller, Eva Friis, Navarro, Francisco, Olaussen Tor, I., Olsen, Are, Ors, Fabien, Otero, Jaime, Pirazzini, Roberta, Poulsen, Michael K., Roden, Nicholas, Rontu, Laura, Serra, Nuno, Shevnina, Elena, Skogen, Morten D., Spreen, Gunnar, Stammer, Detlef, Storheim, Espen, Sørensen, Mathilde B., Tian, Zhongxiang, Triana-Gomez, Arantxa, Valisuo, Ilona, Voss, Peter H., and Walczowski, Waldemar

Subjects
Remote Sensing, Synthesis, Arctic, Observing Systems, In Situ Data, INTAROS, Recommendation, Modelling
Abstract

This report gives an overview of the activities, results and impacts of INTAROS Work Package 6 (WP6). The aim of WP6 is to demonstrate how an integrated observation system can be of specific benefit for society at local, regional or pan-Arctic scale. Through WP6 we show the capability of an enhanced Arctic Observation System towards advancing the economic role of the Arctic by providing support for better-documented processes and better-informed decisions within key sectors such as shipping, petroleum, fishing, and tourism. Further, WP6 demonstrates how the Arctic Observation system may be applied to further develop the accuracy of climate models, improve the understanding of biogeochemical cycles and ecosystem functioning, enhance fisheries and environmental management, increase the level of preparedness towards natural hazards, and develop better management and decision making concepts for selected local communities. Through WP6 INTAROS demonstrates enhanced data search and retrieval, assimilation into models, validation of estimated and projected climate parameters, scientific analysis, decision-support and policy-making. Following a general introduction to INTAROS WP6, eight chapters summarize, for each topic covered, the main activities and results, data and models used, stakeholder/user benefits, and further development and exploitation of results. The topics span broadly and target very different end-user groups but they all share the same overall challenge: how to synthesize data across time and space from different sources, formats and scientific disciplines into aggregated synoptic data products that are relevant for end-users. The following topics are addressed: Improving skill of model predictions in the Arctic, Applying observations and models for environmental and fisheries management, Ice-ocean statistics, Remote sensing applications, Natural hazards in the Arctic, Greenhouse gas exchange in the Arctic, Case studies of community-based observing systems and Benefits of ocean observing for blue growth in the Arctic. The report then describes concrete showcases, software applications. Selected main results across WP6 are then presented, before the report ends with conclusions and perspectives.

Published
2022
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50. Supplementary material to "Greenland and Canadian Arctic ice temperature profiles"

Author

Løkkegaard, Anja, primary, Mankoff, Kenneth, additional, Zdanowicz, Christian, additional, Clow, Gary D., additional, Lüthi, Martin P., additional, Doyle, Samuel, additional, Thomsen, Henrik, additional, Fisher, David, additional, Harper, Joel, additional, Aschwanden, Andy, additional, Vinther, Bo M., additional, Dahl-Jensen, Dorthe, additional, Zekollari, Harry, additional, Meierbachtol, Toby, additional, McDowell, Ian, additional, Humphrey, Neil, additional, Solgaard, Anne, additional, Karlsson, Nanna B., additional, Khan, Shfaqat Abbas, additional, Hills, Benjamin, additional, Law, Robert, additional, Hubbard, Bryn, additional, Christoffersen, Poul, additional, Jacquemart, Mylène, additional, Fausto, Robert S., additional, and Colgan, William T., additional

Published
2022
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