Ice-sheet model SICOPOLIS

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Publications (non-peer-reviewed)

This is a list of non-peer-reviewed publications that use or describe SICOPOLIS.    [Peer-reviewed publications]
Please report any additions or corrections to infosicopolis.net.

❄  Latest count: 58  ❄

2020 and later

Dangleterre, T. 2023.

Influence of basal input data on spin-up simulations of the Antarctic ice sheet.
Master's thesis, Graduate School of Environmental Science, Hokkaido University, Sapporo, Japan, 61 pp.
      DOI

Greve, R. and F. Saito. 2023.

三千年紀の南極氷床の将来変動 (Future change of the Antarctic ice sheet in the 3rd millennium).
In: Giant Reservoirs – Antarctic (GRAntarctic), Project Research Report, March 2023, pp. 212-214. Executive Office of the GRAntarctic Project, National Institute of Polar Research (NIPR), Tachikawa, Tokyo, Japan.
      URL

Gladstone, R. and Y. Wang. 2022.

Antarctic regional inversions using Elmer/Ice: methodology.
Technical report, Zenodo, doi: 10.5281/zenodo.5862046.   DOI

Lin, D. 2022.

Statistic and harmonic analysis of forcing fingerprint on ISMIP6 modeled Greenland ice thickness time series.
Master's thesis, Department of Geology, State University of New York at Buffalo, USA, 88 pp.   URL

MacGregor, J. A., W. Chu, W. T. Colgan, M. A. Fahnestock, D. Felikson, N. B. Karlsson, S. M. J. Nowicki and M. Studinger. 2022.

GBaTSv2: A revised synthesis of the likely basal thermal state of the Greenland Ice Sheet.
The Cryosphere Discussions, doi: 10.5194/tc-2022-40.   DOI

Harada, K. 2021.

南極氷床変動における大気と海洋の役割についての氷床モデル研究
(An ice sheet modelling study on the role of the atmosphere and ocean in Antarctic ice sheet variability).
Master's thesis, Atmosphere and Ocean Research Institute, University of Tokyo, Japan, 102 pp.

Greve, R., R. Calov, T. Obase, F. Saito, S. Tsutaki and A. Abe-Ouchi. 2020.

ISMIP6 future projections for the Antarctic ice sheet with the model SICOPOLIS.
Technical report, Zenodo, doi: 10.5281/zenodo.3971232.   DOI

Greve, R., C. Chambers and R. Calov. 2020.

ISMIP6 future projections for the Greenland ice sheet with the model SICOPOLIS.
Technical report, Zenodo, doi: 10.5281/zenodo.3971251.   DOI

2015–2019

Rezvanbehbahani, S. 2019.

Basal thermal state of the Greenland Ice Sheet.
Doctoral thesis, Department of Geology, University of Kansas, Lawrence, KS, USA, 120 pp.   URL

Scheiter, M. 2019.

Ice flow simulations of the Mocho-Choshuenco ice cap.
Master's thesis, Institute of Geophysics and Geoinformatics, Freiberg University of Mining and Technology, Germany, 75 pp.   URL

Bernales, J. 2018.

Coupling between the Antarctic ice flow, subglacial regimes and regional climate conditions.
Doctoral thesis, Department of Earth Sciences, Free University of Berlin, Germany, 100 pp.   URN

Beyer, S. 2018.

Large-scale modelling of subglacial hydrology.
Doctoral thesis, Faculty of Geosciences, University of Bremen, Germany, 236 pp.   URL

Greve, R. 2018a.

Simulations of the present state and future evolution of the Greenland ice sheet with the model SICOPOLIS.
Teionken News 45, 8-9.   URL

Greve, R. 2018b.

Ice sheets, global warming and sea level.
In: Y. Yamabayashi and M. Kawase (Eds.), Proceedings of the 18th Chitose International Forum on Photonics Science & Technology, pp. 12-17. Chitose Institute of Science and Technology, Japan.   URL

Nordhaus, W. D. 2018.

Global melting? The economics of disintegration of the Greenland Ice Sheet.
NBER Working Paper No. 24640, National Bureau of Economic Research, Cambridge, MA, USA.   URL

Flández, E. 2017.

Modelamiento numérico de la dinámica de la capa de hielo Mocho-Choshuenco
(Numerical modelling of the dynamics of the Mocho-Choshuenco ice cap).
Bachelor's thesis, Faculty of Sciences, Austral University of Chile, Valdivia, Chile, 89 pp.   URL

Greve, R., R. Calov and U. C. Herzfeld. 2017.

Projecting the response of the Greenland ice sheet to future climate change with the ice sheet model SICOPOLIS.
Low Temperature Science 75, 117-129.   DOI

Gölles, T. 2016.

Impurities of glacier ice: accumulation, transport and albedo.
Doctoral thesis, Department of Mathematical Sciences and Technology, Norwegian University of Life Sciences and Department of Arctic Geophysics, University Centre in Svalbard, Norway, 143 pp.   URL

Langebroek, P. M. and K. H. Nisancioglu. 2016.

Moderate Greenland ice sheet melt during the last interglacial constrained by present-day observations and paleo ice core reconstructions.
The Cryosphere Discussions, doi: 10.5194/tc-2016-15.   DOI

Quiquet, A., F. Colleoni and S. Masina. 2016.

Long-term safety of a planned geological repository for spent nuclear fuel in Forsmark, Sweden and Olkiluoto, Finland. Phase 2: impact of ice sheet dynamics, climate forcing and multi-variate sensitivity analysis on maximum ice sheet thickness.
Technical Report TR-16-02,
Swedish Nuclear Fuel and Waste Management Company, Stockholm, Sweden, 105 pp.   URL

Thölix, L., N. Korhonen, A. Venäläinen and H. Korhonen. 2016.

Sensitivity tests and glaciation scenarios of the future with CLIMBER-2–SICOPOLIS model system for Olkiluoto.
Working Report 2016-04, Posiva Oy, Eurajoki, Finland, 66 pp.   URL

2010–2014

Nielsen, E., G. Strykowski, R. Forsberg and F. B. Madsen. 2014.

Estimation of PGR induced absolute gravity changes at Greenland GNET stations.
In: C. Rizos and P. Willis (Eds.), Earth on the Edge: Science for a Sustainable Planet,
International Association of Geodesy Symposia, Vol. 139, pp. 97-102. Springer, Berlin, Heidelberg.   DOI

Haqq-Misra, J., P. Applegate, B. Tuttle, R. Nicholas and K. Keller. 2012.

A computationally efficient model for the Greenland ice sheet.
The Cryosphere Discussions 6, 2751-2788.   DOI

Levermann, A., R. Winkelmann, S. Nowicki, J. L. Fastook, K. Frieler, R. Greve, H. H. Hellmer, M. A. Martin, M. Mengel, A. J. Payne, D. Pollard, T. Sato, R. Timmermann, W. L. Wang and R. A. Bindschadler. 2012.

Projecting Antarctic ice discharge using response functions from SeaRISE ice-sheet models.
The Cryosphere Discussions 6, 3447-3489.   DOI

Sato, T. 2012.

Dynamics of the Antarctic ice sheet with coupled ice shelves.
Doctoral thesis, Graduate School of Environmental Science, Hokkaido University, Sapporo, Japan, 110 pp.
      URL

Ahlkrona, J. 2011.

Implementing higher order dynamics into the ice sheet model SICOPOLIS.
Master's thesis, Department of Information Technology, Uppsala University, Sweden, 49 pp.   URN

Dunse, T. 2011.

Glacier dynamics and subsurface classification of Austfonna, Svalbard: Inferences from observations and modelling.
Doctoral thesis, Faculty of Mathematics and Natural Sciences, University of Oslo, Norway, 175 pp.
      URN

Liakka, J. 2011.

The mutual interaction between the time-mean atmospheric circulation and continental-scale ice sheets.
Doctoral thesis, Faculty of Science, Stockholm University, Sweden, 35 pp.   URN

Robinson, A. 2011.

Modeling the Greenland Ice Sheet response to climate change in the past and future.
Doctoral thesis, Faculty of Science, University of Potsdam, 100 pp.   URN

Gölles, T. 2010.

Modeling oxygen isotopes in polythermal ice sheets.
Master's thesis, Faculty of Natural Sciences, University of Graz, Austria, 108 pp.

2005–2009

Greve, R. and H. Blatter. 2009.

Dynamics of Ice Sheets and Glaciers.
Springer, Berlin, Germany etc., 287 pp.   DOI

Greve, R. and S. Sugiyama. 2009.

Decay of the Greenland Ice Sheet due to surface-meltwater-induced acceleration of basal sliding.
ArXiv E-Prints, arXiv:0905.2027.   DOI

Aðalgeirsdóttir, G., M. Stendel, C. Fox Maule and J. H. Christensen. 2008.

Model setup and first runs with SICOPOLIS ice sheet model and a new geothermal heat flux estimate for the Greenland Ice Sheet.
Danish Climate Centre Report 08-01,
Danish Meteorological Institute, Copenhagen, Denmark, 45 pp.   URL

Greve, R. 2008.

Increased future sea level rise due to rapid decay of the Greenland ice sheet?
In: Proceedings of the First International Symposium on the Arctic Research (ISAR-1), pp. 90-93. Miraikan, Tokyo, Japan.   HUSCAP

Greve, R. 2007.

The polar ice caps of Mars.
Low Temperature Science 66, 139-148.   HUSCAP

Greve, R. and S. Otsu. 2007.

The effect of the north-east ice stream on the Greenland ice sheet in changing climates.
The Cryosphere Discussions 1, 41–76.   DOI

Otsu, S. 2007.

The effect of the North-East Greenland Ice Stream (NEGIS) on the Greenland ice sheet in changing climates.
Master's thesis, Graduate School of Environmental Science, Hokkaido University, Sapporo, Japan, 80 pp.
      HUSCAP

Takahama, R. 2006.

Heinrich Event Intercomparison with the ice-sheet model SICOPOLIS.
Master's thesis, Graduate School of Environmental Science, Hokkaido University, Sapporo, Japan, 63 pp.
      HUSCAP

Vizcaino, M. 2006.

Long-term interactions between ice sheets and climate under anthropogenic greenhouse forcing: Simulations with two complex Earth System Models.
Doctoral thesis, Department of Earth Sciences, University of Hamburg, Germany, 180 pp.
Reports on Earth System Science 30, Max Planck Institute for Meteorology, Hamburg, Germany.   DOI

Forsström, P.-L. 2005.

Through a glacial cycle: simulation of the Eurasian ice sheet dynamics during the last glaciation.
Doctoral thesis, Faculty of Science, University of Helsinki, Finland, 94 pp.
Annales Academiae Scientiarum Fennicae, Geologica-Geographica 168, Helsinki, Finland.

Greve, R. and R. Takahama. 2005.

Simulation of large-scale surges of the glacial Laurentide Ice Sheet: the simplified ISMIP HEINO experiments.
In: Proceedings of the 6th International Conference on Global Change: Connection to the Arctic (GCCA-6), pp. 160-163. Miraikan, Tokyo, Japan.   HUSCAP

Mahajan, R. A. 2005.

Modelling Martian polar caps.
Doctoral thesis, Faculty of Physics, University of Göttingen, Germany, 99 pp.   URL

2000–2004

Greve, R. 2004.

Evolution and dynamics of the Greenland ice sheet over past glacial-interglacial cycles and in future climate-warming scenarios.
In: Proceedings of the 5th International Workshop on Global Change: Connection to the Arctic (GCCA-5), pp. 42-45. University of Tsukuba, Japan.   HUSCAP

Mügge, B. 2004.

Eisalterberechnung am Beispiel des Antarktischen Eisschildes.
Doctoral thesis, Department of Mechanics, Darmstadt University of Technology, Germany, 115 pp.
      URN

Greve, R. 2003.

Inlandeismodelle.
Promet 29 (1-4), 98-104.   HUSCAP

Hutter, K., R. Greve and R. Calov. 2003.

Klimarekonstruktion aus dem Eis großer Eisschilde.
In: Thema Forschung 2/2003, pp. 24-32. Darmstadt University of Technology, Germany.

Knell, S. 2003.

Modellierung der isostatischen Verschiebung der Lithosphäre als Reaktion auf eine zeitlich veränderliche Vereisung.
Diploma thesis, Department of Mechanics, Darmstadt University of Technology, Germany, 132 pp.

Greve, R. 2000.

Large-scale glaciation on Earth and on Mars.
Habilitation thesis, Department of Mechanics, Darmstadt University of Technology, Germany, 274 pp.
      URN

1994–1999

Greve, R., B. Mügge, D. R. Baral, O. Albrecht and A. A. Savvin. 1999.

Nested high-resolution modelling of the Greenland Summit region.
In: K. Hutter, Y. Wang and H. Beer (Eds.), Advances in Cold-Region Thermal Engineering and Sciences, pp. 285-306. Springer, Berlin, Germany etc.

Mügge, B., A. A. Savvin, R. Calov and R. Greve. 1999.

Numerical age computation of the Antarctic ice sheet for dating deep ice cores.
In: K. Hutter, Y. Wang and H. Beer (Eds.), Advances in Cold-Region Thermal Engineering and Sciences, pp. 307-318. Springer, Berlin, Germany etc.

Roe, G. H. 1999.

Wobbly winds in an ice age: the mutual interaction between the great continental ice sheets and atmospheric stationary waves.
Doctoral thesis, Department of Earth, Atmospheric, and Planetary Sciences, Massachusetts Institute of Technology, Cambridge, MA, USA, 236 pp.   URL

Savvin, A. A. 1999.

Grenzschichttheorie nichtlinearer Kriechströmungen und ihre Anwendung auf das EPICA-Vorhaben.
Doctoral thesis, Department of Mechanics, Darmstadt University of Technology, Germany, 136 pp.

Huybrechts, P., A. Abe-Ouchi, I. Marsiat, F. Pattyn, T. Payne, C. Ritz and V. Rommelaere. 1998.

Report of the Third EISMINT Workshop on Model Intercomparison.
European Science Foundation, Strasbourg, France, 120 pp.   URL

Mügge, B. 1998.

Eisalterberechnung im antarktischen Eisschild mit einem Algorithmus zur Teilchenverfolgung.
Diploma thesis, Department of Mechanics, Darmstadt University of Technology, Germany, 75 pp.

Dosch, M. 1997.

Simulation der Dynamik des eiszeitlichen nordamerikanischen Eisschildes.
Diploma thesis, Department of Mechanics, Darmstadt University of Technology, Germany, 124 pp.

Hansen, I., R. Greve and K. Hutter. 1996.

Application of a polythermal ice sheet model to the Antarctic ice sheet: Steady-state solution and response to Milankovic cycles.
In: Proceedings of the 5th International Symposium on Thermal Engineering and Sciences for Cold Regions (ed. Y. Lee and W. Hallett), pp. 89-96.

Greve, R. 1995.

Thermomechanisches Verhalten polythermer Eisschilde - Theorie, Analytik, Numerik.
Doctoral thesis, Department of Mechanics, Darmstadt University of Technology, Germany, 226 pp.
      DOI

Greve, R. 1994.

Zwischenbericht zur Dissertation "Thermomechanisches Verhalten polythermer Eisschilde".
Interim report, Department of Mechanics, Darmstadt University of Technology, Germany, 81 pp.
      DOI

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Last modified: 2024-03-19 by Ralf Greve