Search

Your search keyword '"Wouters, Bert"' showing total 21 results
Start Over Author "Wouters, Bert" Database Supplemental Index
21 results on '"Wouters, Bert"'

2. Systematic Errors Observed in CryoSat-2 Elevation Swaths on Mountain Glaciers and Their Implications

Author

Haacker, Jan, Wouters, Bert, and Slobbe, Cornelis

Abstract

Our awareness of ice caps’ and mountain glaciers’ sensitivity to climate change has driven major advances in the application of remote sensing techniques during the past decade. Regarding ESA’s SARIn altimeter CryoSat-2, processing the full waveform to generate swaths of elevation estimates has become standard practice in regions of complex topographies. This technique provides information on areas where we would be blind otherwise. In this article, we discuss systematic errors and analyze their impact on surface elevation measurements and change rates of two test areas. In particular, we focus on periodically occurring errors in elevation swaths, caused by the superposition of coherent signals from range-ambiguous surfaces. They can lead to measurement errors in excess of 10 m, affect most measurements in mountainous regions, are difficult to exclude with established post-processing techniques, and occur repeatedly for satellite revisits introducing a 369-day periodicity—difficult to distinguish from the annual cycle. We show a correlation between derived elevation swaths and the sensor view angle and explore the influence of common data exclusion choices on higher level products. Our results indicate that these systematic errors hold a substantial share of the error budget and that the choice of thresholds impacts higher level products. We conclude that error correlations need to be considered to characterize the data accuracy. With the established data editing strategies, systematic errors prevent resolving seasonal mass changes of single mountain glacier basins and impact aggregates over larger areas or longer periods.

Published
2023
Full Text
View/download PDF

3. Variable temperature thresholds of melt pond formation on Antarctic ice shelves

Author

van Wessem, J. Melchior, van den Broeke, Michiel R., Wouters, Bert, and Lhermitte, Stef

Abstract

It has been argued that the −5 °C annual mean 2 m air temperature isotherm defines a limit of ice shelf viability on the Antarctic Peninsula as melt ponding increases at higher temperatures. It is, however, presently unknown whether this threshold can also be applied to other Antarctic ice shelves. Here we use two present-day and three future high-resolution Antarctic climate simulations to predict warming thresholds for Antarctic ice shelf melt pond formation on the basis of the melt-over-accumulation ratio. The associated warming thresholds match well with observed melt pond volumes and are found to be spatially highly variable and controlled by snow accumulation. For relatively wet ice shelves, the −5 °C temperature threshold was confirmed; but cold and dry ice shelves such as Amery, Ross and Filchner-Ronne are more vulnerable than previously thought, with threshold temperatures well below −15 °C. Coupled Model Intercomparison Project Phase 6 models predict that towards the end of this century these thresholds can be reached on many ice shelves, even on cold ice shelves and under moderate warming scenarios.

Published
2023
Full Text
View/download PDF

4. Automated Segmented-Flow Analysis – NMR with a Novel Fluoropolymer Flow Cell for High-Throughput Screening

Author

Wouters, Bert, Miggiels, Paul, Bezemer, Roland, van der Cruijsen, Elwin A.W., van Leeuwen, Erik, Gauvin, John, Houben, Klaartje, Babu Sai Sankar Gupta, Karthick, Zuijdwijk, Paul, Harms, Amy, Carvalho de Souza, Adriana, and Hankemeier, Thomas

Abstract

High-throughput analysis in fields such as industrial biotechnology, combinatorial chemistry, and life sciences is becoming increasingly important. Nuclear magnetic resonance (NMR) spectroscopy is a powerful technique providing exhaustive molecular information on complex samples. Flow NMR in particular is a cost- and time-efficient method for large screenings. In this study, we have developed a novel 3.0 mm inner diameter polychlorotrifluoroethylene (PCTFE) flow cell for a segmented-flow analysis (SFA) – NMR automated platform. The platform uses FC-72 fluorinated oil and fluoropolymer components to achieve a fully fluorinated flow path. Samples were repeatably transferred from 96-deepwell plates to the flow cell by displacing a fixed volume of oil, with a transfer time of 42 s. 1H spectra were acquired fully automated with 500 and 600 MHz NMR spectrometers. The spectral performance of the novel PCTFE cell was equal to that of commercial glass cells. Peak area repeatability was excellent with a relative standard deviation of 0.1–0.5% for standard samples, and carryover was below 0.2% without intermediate washing. The sample temperature was conditioned by using a thermostated transfer line in order to reduce the equilibration time in the probe and increase the throughput. Finally, analysis of urine samples demonstrated the applicability of this platform for screening complex matrices.

Published
2022
Full Text
View/download PDF

5. Greenland ice sheet climate disequilibrium and committed sea-level rise

Author

Box, Jason E., Hubbard, Alun, Bahr, David B., Colgan, William T., Fettweis, Xavier, Mankoff, Kenneth D., Wehrlé, Adrien, Noël, Brice, van den Broeke, Michiel R., Wouters, Bert, Bjørk, Anders A., and Fausto, Robert S.

Abstract

Ice loss from the Greenland ice sheet is one of the largest sources of contemporary sea-level rise (SLR). While process-based models place timescales on Greenland’s deglaciation, their confidence is obscured by model shortcomings including imprecise atmospheric and oceanic couplings. Here, we present a complementary approach resolving ice sheet disequilibrium with climate constrained by satellite-derived bare-ice extent, tidewater sector ice flow discharge and surface mass balance data. We find that Greenland ice imbalance with the recent (2000–2019) climate commits at least 274 ± 68 mm SLR from 59 ± 15 × 103km2ice retreat, equivalent to 3.3 ± 0.9% volume loss, regardless of twenty-first-century climate pathways. This is a result of increasing mass turnover from precipitation, ice flow discharge and meltwater run-off. The high-melt year of 2012 applied in perpetuity yields an ice loss commitment of 782 ± 135 mm SLR, serving as an ominous prognosis for Greenland’s trajectory through a twenty-first century of warming.

Published
2022
Full Text
View/download PDF

6. Arctic glaciers record wavier circumpolar winds

Author

Sasgen, Ingo, Salles, Annette, Wegmann, Martin, Wouters, Bert, Fettweis, Xavier, Noël, Brice P. Y., and Beck, Christoph

Abstract

Glaciers in the Arctic respond sensitively to climate change, recording the polar amplification of global warming with increasing mass loss. Here, we use glacier mass balances in Svalbard and northern Arctic Canada to categorize tropospheric variability and the associated summer circulation over the Arctic. We establish a link between annual glacier mass balances and their respective atmospheric forcings since 1950 using GRACE/GRACE-FO satellite data (2002–2021), as well as regional climate models and reanalysis data (1950–2019). We find that asynchronous behaviour of mass balance between the regions has become very likely since the early 2000s, exceeding the range of previous decadal variability. Related tropospheric circulation exhibits more meridional patterns, a greater influence of meridional heat advection and a wavier summer circulation. The traceable impact on glacier mass balances emphasizes the importance of dynamic next to thermodynamic climate changes for the future of glacier mass loss, Arctic ecology and societal impacts.

Published
2022
Full Text
View/download PDF

7. Observing and Modeling Ice Sheet Surface Mass Balance

Author

Lenaerts, Jan T. M., Medley, Brooke, Broeke, Michiel R., and Wouters, Bert

Abstract

Surface mass balance (SMB) provides mass input to the surface of the Antarctic and Greenland Ice Sheets and therefore comprises an important control on ice sheet mass balance and resulting contribution to global sea level change. As ice sheet SMB varies highly across multiple scales of space (meters to hundreds of kilometers) and time (hourly to decadal), it is notoriously challenging to observe and represent in models. In addition, SMB consists of multiple components, all of which depend on complex interactions between the atmosphere and the snow/ice surface, large‐scale atmospheric circulation and ocean conditions, and ice sheet topography. In this review, we present the state‐of‐the‐art knowledge and recent advances in ice sheet SMB observations and models, highlight current shortcomings, and propose future directions. Novel observational methods allow mapping SMB across larger areas, longer time periods, and/or at very high (subdaily) temporal frequency. As a recent observational breakthrough, cosmic ray counters provide direct estimates of SMB, circumventing the need for accurate snow density observations upon which many other techniques rely. Regional atmospheric climate models have drastically improved their simulation of ice sheet SMB in the last decade, thanks to the inclusion or improved representation of essential processes (e.g., clouds, blowing snow, and snow albedo), and by enhancing horizontal resolution (5–30 km). Future modeling efforts are required in improving Earth system models to match regional atmospheric climate model performance in simulating ice sheet SMB, and in reinforcing the efforts in developing statistical and dynamic downscaling to represent smaller‐scale SMB processes. Ice sheets, the largest class of glaciers, contain the majority of ice on Earth. The amount of ice contained in ice sheets changes constantly with the addition of new snow and ice, and melting taking place at the surface, base, and terminus of ice sheets. The balance between these inputs and outputs is known as the “mass balance.” Processes affecting the addition and removal of snow on top of the ice sheet are termed the “surface mass balance” and include rainfall, moisture evaporation, snow‐transporting winds, and melting due to temperature changes. Scientists can now monitor these processes with tools on‐site, such as automated weather stations, Global Positioning Systems, and sensors that record high‐energy radiation (cosmic rays) originating outside the Earth's atmosphere. Several methods are also available where Earth‐orbiting satellites measure how ice is changing. Data collected in these ways have revealed how the surface mass balance varies over time and space. A better understanding of these processes is critical to predicting future behavior of ice sheets and their effect on sea level. Improvements to regional‐scale models in the past decade have allowed good simulations of surface mass balance, and the next step is to build models that work at a global scale. Emerging (remote) observational techniques provide enhanced insights in spatial and temporal variability of ice sheet surface mass balance (SMB)Regional climate models can be used to assess ice sheet SMB, although deficiencies remain in representing subgrid processesIn the near future, Earth System Models can be used to assess internal variability, forced change, and positive feedbacks on ice sheet SMB

Published
2019
Full Text
View/download PDF

9. Six Decades of Glacial Mass Loss in the Canadian Arctic Archipelago

Author

Noël, Brice, Berg, Willem Jan, Lhermitte, Stef, Wouters, Bert, Schaffer, Nicole, and Broeke, Michiel R.

Abstract

The Canadian Arctic Archipelago comprises multiple small glaciers and ice caps, mostly concentrated on Ellesmere and Baffin Islands in the northern (NCAA, Northern Canadian Arctic Archipelago) and southern parts (SCAA, Southern Canadian Arctic Archipelago) of the archipelago, respectively. Because these glaciers are small and show complex geometries, current regional climate models, using 5‐ to 20‐km horizontal resolution, do not properly resolve surface mass balance patterns. Here we present a 58‐year (1958–2015) reconstruction of daily surface mass balance of the Canadian Arctic Archipelago, statistically downscaled to 1 km from the output of the regional climate model RACMO2.3 at 11 km. By correcting for biases in elevation and ice albedo, the downscaling method significantly improves runoff estimates over narrow outlet glaciers and isolated ice fields. Since the last two decades, NCAA and SCAA glaciers have experienced warmer conditions (+1.1°C) resulting in continued mass loss of 28.2 ± 11.5 and 22.0 ± 4.5 Gt/year, respectively, more than doubling (11.9 Gt/year) and doubling (11.9 Gt/year) the pre‐1996 average. While the interior of NCAA ice caps can still buffer most of the additional melt, the lack of a perennial firn area over low‐lying SCAA glaciers has caused uninterrupted mass loss since the 1980s. In the absence of significant refreezing capacity, this indicates inevitable disappearance of these highly sensitive glaciers. Outside the ice sheets of Greenland and Antarctica, the Canadian Arctic Archipelago is home to 14% of the world's ice‐covered area. Ice caps can be found on Ellesmere and Baffin Islands in the north and south of the archipelago. Here we present a novel daily, 1 km surface mass balance product for the period 1958–2015 that allows us to quantify the contemporary mass loss of Canadian ice caps and identify the acting processes. The high‐resolution product realistically resolves local patterns of mass change over narrow glaciers and confined ice fields that are often found in the Canadian Arctic. We show that these ice caps have been losing mass for decades and that mass loss accelerated in 1996. This followed a significant warming (+1.1°C), which increased the production of meltwater. While the snow covering the interior of the northern ice caps can still buffer most of this additional melt through refreezing, the lack of a perennial snow cover over low‐lying southern ice caps caused uninterrupted mass loss since the 1980s. If this trend is not reversed, these southern ice caps might disappear within 400 years. The Canadian Arctic Archipelago experienced six decades of glacial mass lossPredominant negative NAO conditions in the last two decades significantly warmed the near‐surface climate, accelerating the mass lossNCAA ice caps compensate enhanced melt through active refreezing in firn, whereas SCAA ice fields lost most of their buffering capacity

Published
2018
Full Text
View/download PDF

10. Revisiting the Past: A comparative study for semantic segmentation of historical images of Adelaide Island using U-nets

Author

Dahle, Felix, Lindenbergh, Roderik, and Wouters, Bert

Abstract

The TriMetrogon Aerial (TMA) archive is an archive of historical images of Antarctica taken by the US Navy between 1940 and 2000 with analogue cameras. The analysis of such historic data can give a view of Antarctica's glaciers predating modern satellite imagery and provide unique insights into the long-term impact of changing climate conditions with essential validation data for climate modelling. However, the lack of semantic information for these images presents a challenge for large-scale computer-driven analysis.

Published
2023
Full Text
View/download PDF

11. Spatial and temporal Antarctic Ice Sheet mass trends, glacio-isostatic adjustment, and surface processes from a joint inversion of satellite altimeter, gravity, and GPS data

Author

Martín-Español, Alba, Zammit-Mangion, Andrew, Clarke, Peter J., Flament, Thomas, Helm, Veit, King, Matt A., Luthcke, Scott B., Petrie, Elizabeth, Rémy, Frederique, Schön, Nana, Wouters, Bert, and Bamber, Jonathan L.

Abstract

We present spatiotemporal mass balance trends for the Antarctic Ice Sheet from a statistical inversion of satellite altimetry, gravimetry, and elastic-corrected GPS data for the period 2003–2013. Our method simultaneously determines annual trends in ice dynamics, surface mass balance anomalies, and a time-invariant solution for glacio-isostatic adjustment while remaining largely independent of forward models. We establish that over the period 2003–2013, Antarctica has been losing mass at a rate of -84 ± 22 Gt yr-1, with a sustained negative mean trend of dynamic imbalance of -111 ± 13 Gt yr-1. West Antarctica is the largest contributor with -112 ± 10 Gt yr-1, mainly triggered by high thinning rates of glaciers draining into the Amundsen Sea Embayment. The Antarctic Peninsula has experienced a dramatic increase in mass loss in the last decade, with a mean rate of -28 ± 7 Gt yr-1and significantly higher values for the most recent years following the destabilization of the Southern Antarctic Peninsula around 2010. The total mass loss is partly compensated by a significant mass gain of 56 ± 18 Gt yr-1in East Antarctica due to a positive trend of surface mass balance anomalies. Simultaneous estimate of ice dynamics, SMB and GIA for the Antarctic Ice Sheet,The total mass loss of the AIS is -84 ± 24 Gt yr-1over 2003–2013West Antarctica is the largest contributor triggered by high thinning rates of glaciers in the ASE

Published
2016
Full Text
View/download PDF

13. A mascon approach to assess ice sheet and glacier mass balances and their uncertainties from GRACE data

Author

Schrama, Ernst J. O., Wouters, Bert, and Rietbroek, Roelof

Abstract

The purpose of this paper is to assess the mass changes of the Greenland Ice Sheet (GrIS), Ice Sheets over Antarctica, and Land glaciers and Ice Caps with a global mascon method that yields monthly mass variations at 10,242 mascons. Input for this method are level 2 data from the Gravity Recovery and Climate Experiment (GRACE) system collected between February 2003 and June 2013 to which a number of corrections are made. With glacial isostatic adjustment (GIA) corrections from an ensemble of models based on different ice histories and rheologic Earth model parameters, we find for Greenland a mass loss of −278 ± 19 Gt/yr. Whereas the mass balances for the GrIS appear to be less sensitive to GIA modeling uncertainties, this is not the case with the mass balance of Antarctica. Ice history models for Antarctica were recently improved, and updated historic ice height data sets and GPS time series have been used to generate new GIA models. We investigated the effect of two new GIA models for Antarctica and found −92 ± 26 Gt/yr which is half of what is obtained with ICE‐5G‐based GIA models, where the largest GIA model differences occur on East Antarctica. The mass balance of land glaciers and ice caps currently stands at −162 ± 10 Gt/yr. With the help of new GIA models for Antarctica, we assess the mass contribution to the mean sea level at 1.47 ± 0.09 mm/yr or 532 ± 34Gt/yr which is roughly half of the global sea level rise signal obtained from tide gauges and satellite altimetry. Consistent method for estimating mass balances from GRACEMascon techniqueEvaluate systematic errors GIA correction

Published
2014
Full Text
View/download PDF

14. GPS‐Observed Elastic Deformation Due to Surface Mass Balance Variability in the Southern Antarctic Peninsula

Author

Koulali, Achraf, Whitehouse, Pippa L., Clarke, Peter J., Broeke, Michiel R., Nield, Grace A., King, Matt A., Bentley, Michael J., Wouters, Bert, and Wilson, Terry

Abstract

In Antarctica, Global Positioning System (GPS) vertical time series exhibit non‐linear signals over a wide range of temporal scales. To explain these non‐linearities, a number of hypotheses have been proposed, among them the short‐term rapid solid Earth response to contemporaneous ice mass change. Here we use GPS vertical time series to reveal the solid Earth response to variations in surface mass balance (SMB) in the Southern Antarctic Peninsula (SAP). At four locations in the SAP we show that interannual variations of SMB anomalies cause measurable elastic deformation. We use regional climate model SMB products to calculate the induced displacement assuming a perfectly elastic Earth. Our results show a reduction of the misfit when fitting a linear trend to GPS time series corrected for the elastic response to SMB variations. Our results imply that, for a better understanding of the glacial isostatic adjustment signal in Antarctica, SMB variability must be considered. The Global Positioning System (GPS) allows us to measure the changing shape of the Earth's surface with high accuracy. These changes reflect multiple processes operating both within the Earth and at the surface. Using continuously recording GPS instruments in the Antarctic Peninsula, we study the response of the solid Earth to seasonal and annual variations in snow and ice accumulation over the past decade. We show that such loading triggers a measurable response that varies between years, complicating efforts to calculate the long‐term Earth response to past ice sheet change. We discuss the importance of our findings for understanding feedbacks between the solid Earth and the Antarctic ice sheet. Global Positioning System time series of vertical deformation in the Southern Antarctic Peninsula show transient signalsModeled elastic deformation due to surface mass balance (SMB) variation can largely explain these signalsConsidering SMB elastic deformation improves estimates of linear vertical velocities Global Positioning System time series of vertical deformation in the Southern Antarctic Peninsula show transient signals Modeled elastic deformation due to surface mass balance (SMB) variation can largely explain these signals Considering SMB elastic deformation improves estimates of linear vertical velocities

Published
2022
Full Text
View/download PDF

15. North Atlantic Cooling is Slowing Down Mass Loss of Icelandic Glaciers

Author

Noël, Brice, Aðalgeirsdóttir, Guðfinna, Pálsson, Finnur, Wouters, Bert, Lhermitte, Stef, Haacker, Jan M., and Broeke, Michiel R.

Abstract

Icelandic glaciers have been losing mass since the Little Ice Age in the mid‐to‐late 1800s, with higher mass loss rates in the early 21st century, followed by a slowdown since 2011. As of yet, it remains unclear whether this mass loss slowdown will persist in the future. By reconstructing the contemporary (1958–2019) surface mass balance of Icelandic glaciers, we show that the post‐2011 mass loss slowdown coincides with the development of the Blue Blob, an area of regional cooling in the North Atlantic Ocean to the south of Greenland. This regional cooling signal mitigates atmospheric warming in Iceland since 2011, in turn decreasing glacier mass loss through reduced meltwater runoff. In a future high‐end warming scenario, North Atlantic cooling is projected to mitigate mass loss of Icelandic glaciers until the mid‐2050s. High mass loss rates resume thereafter as the regional cooling signal weakens. Icelandic glaciers are currently losing mass, but with a recent slowdown in the last decade. We show that this slowdown coincides with the development of an area of regional cooling in the North Atlantic Ocean to the south of Greenland, called Blue Blob. Cooling in the Blue Blob has been mitigating atmospheric warming in Iceland since 2011, reducing glacier melt. In a future warmer climate, North Atlantic cooling is projected to persist until the mid‐2050s, further slowing down mass loss of Icelandic glaciers. High mass loss resumes thereafter as the regional cooling in the Blue Blob weakens. We project daily surface mass balance of Icelandic glaciers at 500 m spatial resolution under a high‐end warming scenario until 2100We correlate the post‐2011 glacier mass loss slowdown with a local cooling in the North Atlantic OceanWe predict that local North Atlantic cooling will continue mitigating Icelandic glaciers mass loss until the mid‐2050s We project daily surface mass balance of Icelandic glaciers at 500 m spatial resolution under a high‐end warming scenario until 2100 We correlate the post‐2011 glacier mass loss slowdown with a local cooling in the North Atlantic Ocean We predict that local North Atlantic cooling will continue mitigating Icelandic glaciers mass loss until the mid‐2050s

Published
2022
Full Text
View/download PDF

16. CO2 laser cordectomy for bilateral vocal-cord paralysis

Author

Holm, Adriaan F., Wouters, Bert, and Van Overbeek, Jos J. M.

Abstract

Bilateral vocal-cord paralysis usually causes dyspnoea with inspiratory stridor. Most patients have a fairly satisfactory voice. The purpose of this paper is to present the results of a series of 24 patients with bilateral vocal-cord paralysis treated by CO2 laser cordectomy during 1978–86. Breathing improved in 19 patients. In most of the patients, however, the voice worsened. If further surgery is necessary this can easily be performed. In appropriate patients the CO2 laser is an ideal surgical tool for the performance of a cordectomy in patients with bilateral vocal-cord paralysis.

Published
1989
Full Text
View/download PDF

17. ICESat‐2 Meltwater Depth Estimates: Application to Surface Melt on Amery Ice Shelf, East Antarctica

Author

Fricker, Helen Amanda, Arndt, Philipp, Brunt, Kelly M., Datta, Rajashree Tri, Fair, Zachary, Jasinski, Michael F., Kingslake, Jonathan, Magruder, Lori A., Moussavi, Mahsa, Pope, Allen, Spergel, Julian J., Stoll, Jeremy D., and Wouters, Bert

Abstract

Surface melting occurs during summer on the Antarctic and Greenland ice sheets, but the volume of stored surface meltwater has been difficult to quantify due to a lack of accurate depth estimates. NASA's ICESat‐2 laser altimeter brings a new capability: photons penetrate water and are reflected from both the water and the underlying ice; the difference provides a depth estimate. ICESat‐2 sampled Amery Ice Shelf on January 2, 2019 and showed double returns from surface depressions, indicating meltwater. For four melt features, we compared depth estimates from eight algorithms: six based on ICESat‐2 and two from coincident Landsat‐8 and Sentinel‐2 imagery. All algorithms successfully identified surface water at the same locations. Algorithms based on ICESat‐2 produced the most accurate depths; the image‐based algorithms underestimated depths (by 30%–70%). This implies that ICESat‐2 depths can be used to tune image‐based algorithms, moving us closer to quantifying stored meltwater volumes across Antarctica and Greenland. Summer surface melting on Antarctica's ice shelves is a small component of overall ice sheet mass loss but can be important for individual ice shelves and may increase as the climate warms. However, the volume of meltwater has been difficult to monitor because depth estimates are challenging. NASA's ICESat‐2 laser altimetry mission brings a new capability to this problem. ICESat‐2 532 nm photons (green light) are able to pass through water and reflect from both the water surface and the underlying ice surface; the difference in elevation provides meltwater depth estimates. In this pilot study, we compared depths from eight algorithms (six ICESat‐2 and two image based) over four Amery Ice Shelf meltwater lakes for an ICESat‐2 pass in early January 2019. The ICESat‐2 algorithms all produced more reliable depth estimates, and the image‐based algorithms underestimated the depths. This implies that ICESat‐2 water depths can be used to tune image‐based depth retrieval algorithms, enabling improved performance and allowing us to estimate more accurately how much surface melt is stored in melt ponds on the ice sheets each summer. ICESat‐2 photons penetrate surface melt lakes and reflect from both the water surface and the underlying ice, providing depth estimatesWe compared depths from eight algorithms (six ICESat‐2 and two image‐based) for four lakes present on Amery Ice Shelf in January 2019Depths from ICESat‐2 were more accurate than from imagery (30%–70% too low); merging these data will improve estimates ice‐sheet wide ICESat‐2 photons penetrate surface melt lakes and reflect from both the water surface and the underlying ice, providing depth estimates We compared depths from eight algorithms (six ICESat‐2 and two image‐based) for four lakes present on Amery Ice Shelf in January 2019 Depths from ICESat‐2 were more accurate than from imagery (30%–70% too low); merging these data will improve estimates ice‐sheet wide

Published
2021
Full Text
View/download PDF

18. JOINT INVERSION ESTIMATE OF REGIONAL GLACIAL ISOSTATIC ADJUSTMENT IN ANTARCTICA CONSIDERING A LATERAL VARYING EARTH STRUCTURE (ESA STSE PROJECT REGINA).

Author

Sasgen, Ingo, Martín-Español, Alba, Horvath, Alexander, Klemann, Volker, Petrie, Elizabeth J., Wouters, Bert, Horwath, Martin, Pail, Roland, Bamber, Jonathan L., Clarke, Peter J., Konrad, Hannes, and Drinkwater, Mark R.

Abstract

The mass balance of the Antarctic ice sheet from satellite gravimetry, and to a lesser extent altimetry, observations remains uncertain due to the poorly known correction for the glacial isostatic adjustment of the solid Earth (GIA). Although much progress has been made in consistently modelling ice-sheet evolu-tion, related bedrock deformation and sea-level change, predictions of GIA remain ambiguous due to the lack of observational constraints in Antarctica. Here, we present an improved GIA estimate based on the joint inversion of GRACE, Envisat/ICESat and GPS measurements, making use of the different sen-sitivities of the satellite observations to surface-mass and solid Earth processes. We base our joint inver-sion on viscoelastic response functions to a disc load forcing, allowing us to account for lateral variations in the lithosphere thickness and mantle viscosity in Antarctica. Our estimate is able to reproduce extreme GPS-measured uplift rates (up to 3 cm yr-1) in the Amundsen Sea Embayment, indicating that large parts of the uplift are caused by GIA induced by recent load changes in the presence of a low-viscosity upper mantle. We compare our GIA inversion estimate with the prediction obtained with a coupled model of the ice sheet and solid Earth, as well as with published estimates. We evaluate its impact on the determination of ice-mass balance in Antarctica from gravimetry and altimetry. The results present-ed here are the final results of the Support To Science Element Project REGINA and its Supplementary Study of the European Space Agency, www.regina-science.eu. [ABSTRACT FROM AUTHOR]

Published
2018

19. A NEW GLACIAL-ISOSTATIC ADJUSTMENT MODEL FOR GREENLAND CONSTRAINED BY GPS UPLIFT RATES AND RELATIVE SEA-LEVEL DATA.

Author

Sasgen, Ingo, Khan, Shafqat Abbas, Wouters, Bert, and Woodroffe, Sarah

Abstract

The bedrock displacement recorded with GNET-GPS stations in Greenland reveal viscoelastic uplift rates that strongly contradict published predictions of glacial-isostatic adjustment (GIA). In particular, GPS provides evidence that GIA-induced uplift rates are considerably higher in the northwest and southeast of the ice sheet. Both regions are characterized by a lack of relative sea level (RSL) data to constrain the past ice sheet evolution and related viscoelastic displacement, thus causing large uncer-tainties in GIA predictions. Here, we develop a new GIA prediction by adjusting the geomorphological ice-sheet reconstruction of Fleming & Lambeck (2004) simultaneously to the RSL indicators and the newly available GPS data. Special focus lies on south Greenland, where an increasing number of high-quality RSL indicators from isolation basins suggest a fast relaxation of the solid Earth. This finding is consistent with global seismic models indicating a gradient in the lithosphere thickness and astheno-sphere viscosity from high values in the northwest to low values in the southeast. We demonstrate that the GIA prediction fits the GPS and RSL data significantly better for a lateral varying distribution of Earth model parameters. Finally, we evaluate the impact of our new GIA model on determining ice-mass bal-ances from GRACE. We show that commonly used GIA predictions have underestimated the solid Earth response by 17 Gt/yr, which is about 7 % of Greenland current ice-mass loss. [ABSTRACT FROM AUTHOR]

Published
2018

21. Dextrocardia?

Author

Mannes, Gregor P.M., Jagt, Eric J. van der, Wouters, Bert, and Postmus, Pieter E.

Published
1989
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results