Your search keyword '"Hurkmans, R."' showing total 12 results

1. Compassion: A Paradox in Art and Society

Author

Boomgaard, J., Hurkmans, R., Westerveld, J., and ASCA (FGw)

Abstract

Compassion: A Paradox in Art and Society investigates what space an artwork can occupy in the public domain, how it can draw attention to ethical issues in society, and how it can spur individuals and groups into action. The starting point for this theoretical and practice-based exploration is the conceptual artwork Flag of Compassion, initiated by Rini Hurkmans.

Published

2017

2. Mobile Meaning

Author

Boomgaard, J., Hurkmans, R., Westerveld, J., and ASCA (FGw)

Published

2017

3. The land-ice contribution to 21st-century dynamic sea level rise

Author

Howard, T., Ridley, J., Pardaens, A. K., Hurkmans, R. T. W. L., Payne, A. J., Giesen, R. H., Lowe, J. A., Bamber, J. L., Edwards, T. L., Oerlemans, J., Sub Dynamics Meteorology, Marine and Atmospheric Research, Sub Dynamics Meteorology, and Marine and Atmospheric Research

Subjects

010504 meteorology & atmospheric sciences, SURFACE MASS-BALANCE, Greenland ice sheet, Ice-albedo feedback, CLIMATE-MODEL, Antarctic sea ice, 010502 geochemistry & geophysics, 01 natural sciences, SHEET MODEL, Sea ice, Cryosphere, SOUTHERN-OCEAN, Sea ice concentration, lcsh:Environmental sciences, 0105 earth and related environmental sciences, lcsh:GE1-350, geography, geography.geographical_feature_category, FRESH-WATER, SPATIAL SENSITIVITIES, lcsh:Geography. Anthropology. Recreation, CENTENNIAL VARIABILITY, Arctic ice pack, ATLANTIC THERMOHALINE CIRCULATION, lcsh:G, 13. Climate action, Climatology, GLACIER CONTRIBUTIONS, Sea ice thickness, MERIDIONAL OVERTURNING CIRCULATION, Geology

Abstract

Climate change has the potential to influence global mean sea level through a number of processes including (but not limited to) thermal expansion of the oceans and enhanced land ice melt. In addition to their contribution to global mean sea level change, these two processes (among others) lead to local departures from the global mean sea level change, through a number of mechanisms including the effect on spatial variations in the change of water density and transport, usually termed dynamic sea level changes.\ud \ud In this study, we focus on the component of dynamic sea level change that might be given by additional freshwater inflow to the ocean under scenarios of 21st-century land-based ice melt. We present regional patterns of dynamic sea level change given by a global-coupled atmosphere–ocean climate model forced by spatially and temporally varying projected ice-melt fluxes from three sources: the Antarctic ice sheet, the Greenland Ice Sheet and small glaciers and ice caps. The largest ice melt flux we consider is equivalent to almost 0.7m of global mean sea level rise over the 21st century. The temporal evolution of the dynamic sea level changes, in the presence of considerable variations in the ice melt flux, is also analysed.\ud \ud We find that the dynamic sea level change associated with the ice melt is small, with the largest changes occurring in the North Atlantic amounting to 3 cm above the global mean rise. Furthermore, the dynamic sea level change associated with the ice melt is similar regardless of whether the simulated ice fluxes are applied to a simulation with fixed CO2 or under a business-as-usual greenhouse gas warming scenario of increasing CO2.

Published

2014

4. ESA's ice sheets CCI: Validation and inter-comparison of surface elevation changes derived

Author

Levinsen, J.F., Khvorostovsky, K., Ticconi, F., Shepherd, A., Forsberg, R., Sørensen, L.S., Muir, A., Pie, N., Felikson, D., Flament, T., Hurkmans, R., Moholdt, G., Gunter, B.C., Lindenbergh, R.C., and Kleinherenbrink, M.

Abstract

In order to increase the understanding of the changing climate, the European Space Agency has launched the Climate Change Initiative (ESA CCI), a program which joins scientists and space agencies into 13 projects either affecting or affected by the concurrent changes. 5 This work is part of the Ice Sheets CCI and four parameters are to be determined for the Greenland Ice Sheet (GrIS), each resulting in a dataset made available to the public: Surface Elevation Changes (SEC), surface velocities, grounding line locations, and calving front locations. All CCI projects have completed a so-called Round Robin exercise in which the scientific community was asked to provide their 10 best estimate of the sought parameters as well as a feedback sheet describing their work. By inter-comparing and validating the results, obtained from research institutions world-wide, it is possible to develop the most optimal method for determining each parameter. This work describes the SEC Round Robin and the subsequent conclusions leading to the creation of a method for determining GrIS SEC values. The participants 15 used either Envisat radar or ICESat laser altimetry over Jakobshavn Isbræ drainage basin, and the submissions led to inter-comparisons of radar vs. altimetry as well as cross-over vs. repeat-track analyses. Due to the high accuracy of the former and the high spatial resolution of the latter, a method, which combines the two techniques will provide the most accurate SEC estimates. The data supporting the final GrIS analysis 20 stem from the radar altimeters on-board Envisat, ERS-1 and ERS-2. The accuracy of laser data exceeds that of radar altimetry; the Round Robin analysis has, however, proven the latter equally capable of dealing with surface topography thereby making such data applicable in SEC analyses extending all the way from the interior ice sheet to margin regions. This shows good potential for a future inclusion of ESA CryoSat-2 25 and Sentinel-3 radar data in the analysis, and thus for obtaining reliable SEC estimates throughout the entire GrIS.

Published

2013

5. Runoff Prediction in Ungauged Basins Synthesis across Processes, Places and Scales

Author

Dunne, T, Blöschl, G, Sivapalan, M, Wagener, T, Viglione, A, Savenije, H, Goodrich, D, Gupta, H. V., Tachikawa, Y, Troch, P, Weiler, M, Mcglynn, B, Borga, M, Bormann, H, Hurkmans, R, Komma, J, Nandagiri, L, Uijlenhoet, R, Tetzlaff, D, Al Rawas, G, Carey, S. K., Fan, Y, Hrachowitz, M, Kirnbauer, R, Jewitt, G, Laudon, H, Mcguire, K. J., Sayama, T, Soulsby, C, Zehe, E, Mcmahon, T, Laaha, G, Parajka, J, Peel, M. C., Szolgay, J, Thompson, S, Woods, R, Yang, D, Weingartner, R, Hannah, D. M., Marks, D, Pearson, C, Rogger, M, Salinas, J. L., Sauquet, E, Srikanthan, S, Castellarin, A, Botter, G, Hughes, D. A., Liu, S, Ouarda, T. B. M. J., Post, D, Spence, C, Vogel, R. M., Demuth, S, Hisdal, H, Kroll, C. N., van Lanen, H. A. J., Nester, T, Tallaksen, L. M., Young, A, Rosbjerg, D, Burn, D. H., Croke, B, Di Baldassarre, G, Iacobellis, Vito, Kjeldsen, T, Kuczera, G, Merz, R, Montanari, A, Morris, D, Ren, L, Toth, E, Andréassian, V, Archfield, S, Bárdossya, Chiew, F, Duan, Q, Gelfan, A, Hlavčová, K, Mcintyre, N, Oudin, L, Perrin, C, Skøien, J. O., Zhang, Y, Biggs, T, Jia, S, Korytny, L. M., Gartsman, B, Pomeroy, J. W., Shook, K, Fang, X, Brown, T, Samuel, J, Coulibaly, P, Metcalfe, R. A., Humer, G, Rahman, A, Haddad, K, Weinmann, E, Blume, T, Crabit, A, Colin, F, Moussa, R, Winsemius, H, Liebe, J, van de Giesen, N, Walter, M. T., Steenhuis, T. S., Kennedy, J. R., Unkrich, C. L., Mazvimavi, D, Viney, N. R., Takeuchi, K, Hapuarachchi, H. A. P., Kiem, A. S., Ishidaira, H, Ao, T, Magome, J, Zhou, M. C., Georgievski, M, Wang, G, Yoshimura, C, Arheimer, B, Lindström, G, Mcdonnell, J, Schaake, J, Young, G, and Lin, S.

Published

2013

6. Improved ice loss estimate of the northwestern Greenland ice sheet

Author

Kjeldsen, K., Khan, S., Wahr, J., Korsgaard, N., Kjaer, K., Bjørk, A., Hurkmans, R., van den Broeke, M., Bamber, J., and van Angelen, J.

Published

2013

7. Evaluation of satellite soil moisture retrieval algorithms using AMSR - E data

Author

Hurkmans, R., Su, Zhongbo, Jackson, T.J., Teuling, A.J., Leijnse, H., Troch, P.A., Sheffield, J., Wood, E.F., Faculty of Geo-Information Science and Earth Observation, Department of Water Resources, and UT-I-ITC-WCC

Subjects

ADLIB-ART-1196, WRS

Published

2004

8. Studenten maken begin met 3D geo-visualisatie van lichthinder

Author

Biemans, H., Flierman, R., Hoogerwerf, T., Hurkmans, R., Strikers, T., Verhagen, S., van Lammeren, R.J.A., and de Bruin, S.

Subjects

Life Science

Published

2002

9. The gravitationally consistent sea-level fingerprint of future terrestrial ice loss

Author

Spada, G., Bamber, J. L., and Hurkmans, R. T. W. L.

Subjects

13. Climate action, terrestrial ice loss, Astrophysics::Earth and Planetary Astrophysics, future sea level change, Physics::Atmospheric and Oceanic Physics, Physics::Geophysics

Abstract

We solve the sea-level equation to investigate the pattern of the gravitationally self-consistent sea-level variations (fingerprints) corresponding to modeled scenarios of future terrestrial ice melt. These were obtained from separate ice dynamics and surface mass balance models for the Greenland and Antarctic ice sheets and by a regionalized mass balance model for glaciers and ice caps. For our mid-range scenario, the ice melt component of total sea-level change attains its largest amplitude in the equatorial oceans, where we predict a cumulative sea-level rise of ~ 25 cm and rates of change close to 3 mm/yr from ice melt alone by 2100. According to our modeling, in low-elevation densely populated coastal zones, the gravitationally consistent sea-level variations due to continental ice loss will range between 50 and 150% of the global mean. This includes the effects of glacial-isostatic adjustment, which mostly contributes across the lateral forebulge regions in North America. While the mid range ocean-averaged elastic-gravitational sea-level variations compare with those associated with thermal expansion and ocean circulation, their combination shows a complex regional pattern, where the former component dominates in the Equatorial Pacific Ocean and the latter in the Arctic Ocean.

10. The national airborne field experiment data sets

Author

Jeffrey Walker, Balling, J., Bell, M., Berg, A., Berger, M., Biasoni, D., Botha, E., Boulet, G., Chen, Y., Christen, E., Dejeu, R., Derosnay, P., Dever, C., Draper, C., Fenollar, J., Gomez, C., Grant, J. P., Hacker, J., Hafeez, M., Hancock, G., Hansen, D., Holz, L., Hornbuckle, J., Hurkmans, R., Jackson, T., Johanson, J., Jones, P., Jones, S., Kalma, J., Kerr, Y., Kim, E., Kuzmin, V., Lakshmi, V., Lopez, E., Maggioni, V., Maisongrande, P., Martinez, C., Mckee, L., Merlin, O., Mladenova, I., O Neill, P., Panciera, R., Paruscio, V., Pipunic, R., Rawls, W., Rinaldi, M., Rüdiger, C., Saco, P., Saleh, K., Savstrup-Kristensen, S., Shoemark, V., Skou, N., Soebjaerg, S., Summerell, G., Teuling, A. J., Thompson, H., Thyer, M., Toyra, J., Tsang, A., Wells, T., Wursteisen, P., and Young, R.

11. The National Airborne Field Experiment Data Sets

Author

Walker, J. P., Balling, J., Bell, M., Berg, A., Berger, M., Biasoni, D., Botha, E., Boulet, G., Chen, Y., Christen, E., Dejeu, R., Derosnay, P., Dever, C., Clara Draper, Fenollar, J., Gomez, C., Grant, J. P., Hacker, J., Hafeez, M., Hancock, G., Hansen, D., Holz, L., Hornbuckle, J., Hurkmans, R., Jackson, T., Johanson, J., Jones, P., Jones, S., Kalma, J., Kerr, Y., Kim, E., Kuzmin, V., Lakshmi, V., Lopez, E., Maggioni, V., Maisongrande, P., Martinez, C., Mckee, L., Merlin, O., Mladenova, I., O Neill, P., Panciera, R., Paruscio, V., Pipunic, R., Rawls, W., Rinaldi, M., Ruediger, C., Saco, P., Saleh, K., Savstrup-Kristensen, S., Shoemark, V., Skou, N., Soebjaerg, S., Summerell, G., Teuling, A. J., Thompson, H., Thyer, M., Toyra, J., Tsang, A., Wells, T., Wursteisen, P., Young, R., Oxley, L., and Kulasiri, D.

12. Sources of 21st century regional sea level rise along the coast of North-West Europe

Author

Giorgio Spada, Jeff Ridley, Jason Lowe, David G. Vaughan, Tom Howard, Anne Pardaens, Jonathan L. Bamber, R. T. W. L. Hurkmans, Howard, T., Pardaens, A. K., Bamber, J. L., Ridley, J., SPADA, GIORGIO, Hurkmans, R. T. W. L., Lowe, J. A., Vaughan, D., T. Howard, A. K. Pardaen, J. A. Lowe, J. Ridley, R. T. W. L. Hurkman, J. L. Bamber, G. Spada, and D. Vaughan

Subjects

climate effect, 010504 meteorology & atmospheric sciences, Ice stream, Climate change, Storm surge, NN, 010502 geochemistry & geophysics, ice flow, 01 natural sciences, oceanic circulation, twenty first centur, Sea level, lcsh:Environmental sciences, thermal expansion, 0105 earth and related environmental sciences, lcsh:GE1-350, geography, geography.geographical_feature_category, Flood myth, Ocean current, lcsh:Geography. Anthropology. Recreation, Glacier, climate forcing, coastal zone, sea level change, lcsh:G, 13. Climate action, Climatology, Environmental science, Ice sheet

Abstract

Changes in both global and regional mean sea level, and changes in the magnitude of extreme flood heights, are the result of a combination of several distinct contributions most, but not all, of which are associated with climate change. These contributions include effects in the solid earth, gravity field, changes in ocean mass due to ice loss from ice sheets and glaciers, thermal expansion, alterations in ocean circulation driven by climate change and changing freshwater fluxes, and the intensity of storm surges. Due to the diverse range of models required to simulate these systems, the contributions to sea-level change have usually been discussed in isolation rather than in one self-consistent assessment. Focusing on the coastline of northwest Europe, we consider all the processes mentioned above and their relative impact on 21st century regional mean sea levels and the 50-year return flood height. As far as possible our projections of change are derived from process-based models forced by the A1B emissions scenario to provide a self-consistent comparison of the contributions. We address uncertainty by considering both a mid-range and an illustrative high-end combination of the different components. For our mid-range ice loss scenario we find that thermal expansion of seawater is the dominant contributor to change in northwest European sea level by 2100. However, the projected contribution to extreme sea level, due to changes in storminess alone, is in some places significant and comparable to the global mean contribution of thermal expansion. For example, under the A1B emissions scenario, by 2100, change in storminess contributes around 15 cm to the increase in projected height of the 50-year storm surge on the west coast of the Jutland Peninsula, compared with a contribution of around 22 cm due to thermal expansion and a total of 58 cm from all of the contributions we consider. An illustrative combination of our high-end projections suggests increases in the 50-year return level of 86 cm at Sheerness, 95 cm at Roscoff, 106 cm at Esbjerg, and 67cm at Bergen. The notable regional differences between these locations arise primarily from differences in the rates of vertical land movement and changes in storminess.

Published

2013