Ice-sheet model SICOPOLIS

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Publications

This is a list of peer-reviewed publications that use or describe SICOPOLIS. [Non-peer-reviewed publications]
Please report any additions or corrections to info <at-nospam> sicopolis.net.

❄ Latest count: 153 ❄

2024

Höning, D., M. Willeit and A. Ganopolski. 2024.: Reversibility of Greenland ice sheet mass loss under artificial carbon dioxide removal scenarios.
Environmental Research Letters 19 (2), 024038. DOI
Willeit, M., R. Calov, S. Talento, R. Greve, J. Bernales, V. Klemann, M. Bagge and A. Ganopolski. 2024.: Glacial inception through rapid ice area increase driven by albedo and vegetation feedbacks.
Climate of the Past 20 (3), 597-623. DOI

2023

Gaikwad, S. S., L. Hascoet, S. H. K. Narayanan, L. Curry-Logan, R. Greve and P. Heimbach. 2023.: SICOPOLIS-AD v2: tangent linear and adjoint modeling framework for ice sheet modeling enabled by automatic differentiation tool Tapenade.
Journal of Open Source Software 8 (83), 4679. DOI
Greve, R., C. Chambers, T. Obase, F. Saito, W.-L. Chan and A. Abe-Ouchi. 2023.: Future projections for the Antarctic ice sheet until the year 2300 with a climate-index method.
Journal of Glaciology, doi: 10.1017/jog.2023.41. DOI
Höning, D., M. Willeit, R. Calov, V. Klemann, M. Bagge and A. Ganopolski. 2023.: Multistability and transient response of the Greenland ice sheet to anthropogenic CO2 emissions.
Geophysical Research Letters 50 (6), e2022GL101827. DOI
Moore, J. C., R. Greve, C. Yue, T. Zwinger, F. Gillet-Chaulet and L. Zhao. 2023.: Reduced ice loss from Greenland under stratospheric aerosol injection.
Journal of Geophysical Research: Earth Surface 128 (11), e2023JF007112. DOI
Seroussi, H., V. Verjans, S. Nowicki, A. J. Payne, H. Goelzer, W. H. Lipscomb, A. Abe-Ouchi, C. Agosta, T. Albrecht, X. Asay-Davis, A. Barthel, R. Calov, R. Cullather, C. Dumas, B. K. Galton-Fenzi, R. Gladstone, N. R. Golledge, J. M. Gregory, R. Greve, T. Hattermann, M. J. Hoffman, A. Humbert, P. Huybrechts, N. C. Jourdain, T. Kleiner, E. Larour, G. R. Leguy, D. P. Lowry, C. M. Little, M. Morlighem, F. Pattyn, T. Pelle, S. F. Price, A. Quiquet, R. Reese, N.-J. Schlegel, A. Shepherd, E. Simon, R. S. Smith, F. Straneo, S. Sun, L. D. Trusel, J. Van Breedam, P. Van Katwyk, R. S. W. van de Wal, R. Winkelmann, C. Zhao, T. Zhang and T. Zwinger. 2023.: Insights into the vulnerability of Antarctic glaciers from the ISMIP6 ice sheet model ensemble and associated uncertainty.
The Cryosphere 17 (12), 5197-5217. DOI

2022

Chambers, C., R. Greve, T. Obase, F. Saito and A. Abe-Ouchi. 2022.: Mass loss of the Antarctic ice sheet until the year 3000 under a sustained late-21st-century climate.
Journal of Glaciology 68 (269), 605-617. DOI
Greve, R. and C. Chambers. 2022.: Mass loss of the Greenland ice sheet until the year 3000 under a sustained late-21st-century climate.
Journal of Glaciology 68 (269), 618-624. DOI
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 16 (8), 3033-3049. DOI
Wang, Y., C. Zhao, R. Gladstone, B. Galton-Fenzi and R. Warner. 2022.: Thermal structure of the Amery Ice Shelf from borehole observations and simulations.
The Cryosphere 16 (4), 1221–1245. DOI
Willeit, M., A. Ganopolski, A. Robinson and N. R. Edwards. 2022.: The Earth system model CLIMBER-X v1.0 – Part 1: Climate model description and validation.
Geoscientific Model Development 15 (14), 5905-5948. DOI

2021

Edwards, T. L., S. Nowicki, B. Marzeion, R. Hock, H. Goelzer, H. Seroussi, C. J. Smith, N. C. Jourdain, D. Slater, C. M. McKenna, E. Simon, A. Abe-Ouchi, J. M. Gregory, E. Larour, W. H. Lipscomb, A. J. Payne, A. Shepherd, F. Turner, C. Agosta, P. Alexander, T. Albrecht, B. Anderson, X. Asay-Davis, A. Aschwanden, A. Barthel, A. Bliss, R. Calov, C. Chambers, N. Champollion, Y. Choi, R. Cullather, J. Cuzzone, C. Dumas, D. Felikson, X. Fettweis, K. Fujita, B. K. Galton-Fenzi, R. Gladstone, N. R. Golledge, R. Greve, T. Hattermann, M. J. Hoffman, A. Humbert, M. Huss, P. Huybrechts, W. Immerzeel, T. Kleiner, P. Kraaijenbrink, S. Le clec'h, V. Lee, G. R. Leguy, C. M. Little, D. P. Lowry, J.-H. Malles, D. F. Martin, F. Maussion, M. Morlighem, J. F. O'Neill, I. Nias, F. Pattyn, T. Pelle, S. Price, A. Quiquet, V. Radić, R. Reese, D. R. Rounce, M. Rückamp, A. Sakai, C. Shafer, N.-J. Schlegel, S. Shannon, R. S. Smith, F. Straneo, S. Sun, L. Tarasov, L. D. Trusel, J. Van Breedam, R. van de Wal, M. van den Broeke, R. Winkelmann, H. Zekollari, C. Zhao, T. Zhang and T. Zwinger. 2021.: Projected land ice contributions to twenty-first-century sea level rise.
Nature 593 (7857), 74-82. DOI
Goto-Azuma, K., T. Homma, T. Saruya, F. Nakazawa, Y. Komuro, N. Nagatsuka, M. Hirabayashi, Y. Kondo, M. Koike, T. Aoki, R. Greve and J. Okuno. 2021.: Studies on the variability of the Greenland Ice Sheet and climate.
Polar Science 27, 100557. DOI
Mas e Braga, M., J. Bernales, M. Prange, A. P. Stroeven and I. Rogozhina. 2021.: Sensitivity of the Antarctic ice sheets to the warming of marine isotope substage 11c.
The Cryosphere 15 (1), 459-478. DOI
Payne, A. J., S. Nowicki, A. Abe-Ouchi, C. Agosta, P. Alexander, T. Albrecht, X. Asay-Davis, A. Aschwanden, A. Barthel, T. J. Bracegirdle, R. Calov, C. Chambers, Y. Choi, R. Cullather, J. Cuzzone, C. Dumas, T. L. Edwards, D. Felikson, X. Fettweis, B. K. Galton-Fenzi, H. Goelzer, R. Gladstone, N. R. Golledge, J. M. Gregory, R. Greve, T. Hattermann, M. J. Hoffman, A. Humbert, P. Huybrechts, N. C. Jourdain, T. Kleiner, P. Kuipers Munneke, E. Larour, S. Le clec'h, V. Lee, G. Leguy, W. H. Lipscomb, C. M. Little, D. P. Lowry, M. Morlighem, I. Nias, F. Pattyn, T. Pelle, S. F. Price, A. Quiquet, R. Reese, M, Rückamp, N.-J. Schlegel, H. Seroussi, A. Shepherd, E. Simon, D. Slater, R. S. Smith, F. Straneo, S, Sun, L. Tarasov, L. D. Trusel, J. Van Breedam, R. van de Wal, M. van den Broeke, R. Winkelmann, C. Zhao, T. Zhang and T. Zwinger. 2021.: Future sea level change under Coupled Model Intercomparison Project Phase 5 and Phase 6 scenarios from the Greenland and Antarctic ice sheets.
Geophysical Research Letters 48 (16), e2020GL091741. DOI
Scheiter, M., M. Schaefer, E. Flández, D. Bozkurt and R. Greve. 2021.: The 21st-century fate of the Mocho-Choshuenco ice cap in southern Chile.
The Cryosphere 15 (8), 3637-3654. DOI

2020

Chambers, C., R. Greve, B. Altena and P.-M. Lefeuvre. 2020.: Possible impacts of a 1000 km long hypothetical subglacial river valley towards Petermann Glacier in northern Greenland.
The Cryosphere 14 (11), 3747-3759. DOI
Goelzer, H., S. Nowicki, A. Payne, E. Larour, H. Seroussi, W. H. Lipscomb, J. Gregory, A. Abe-Ouchi, A. Shepherd, E. Simon, C. Agosta, P. Alexander, A. Aschwanden, A. Barthel, R. Calov, C. Chambers, Y. Choi, J. Cuzzone, C. Dumas, T. Edwards, D. Felikson, X. Fettweis, N. R. Golledge, R. Greve, A. Humbert, P. Huybrechts, S. Le clec'h, V. Lee, G. Leguy, C. Little, D. P. Lowry, M. Morlighem, I. Nias, A. Quiquet, M. Rückamp, N.-J. Schlegel, D. Slater, R. Smith, F. Straneo, L. Tarasov, R. van de Wal and M. van den Broeke. 2020.: The future sea-level contribution of the Greenland ice sheet: a multi-model ensemble study of ISMIP6.
The Cryosphere 14 (9), 3071-3096. DOI
Goto-Azuma, K., T. Homma, T. Saruya, F. Nakazawa, Y. Komuro, N. Nagatsuka, M. Hirabayashi, Y. Kondo, M. Koike, T. Aoki, R. Greve and J. Okuno. 2020.: Studies on the variability of the Greenland Ice Sheet and climate.
Polar Science, doi: 10.1016/j.polar.2020.100557. DOI
Levermann, A., R. Winkelmann, T. Albrecht, H. Goelzer, N. R. Golledge, R. Greve, P. Huybrechts, J. Jordan, G. Leguy, D. Martin, M. Morlighem, F. Pattyn, D. Pollard, A. Quiquet, C. Rodehacke, H. Seroussi, J. Sutter, T. Zhang, J. Van Breedam, R. Calov, R. DeConto, C. Dumas, J. Garbe, G. H. Gudmundsson, M. J. Hoffman, A. Humbert, T. Kleiner, W. H. Lipscomb, M. Meinshausen, E. Ng, S. M. J. Nowicki, M. Perego, S. F. Price, F. Saito, N.-J. Schlegel, S. Sun and R. S. W. van de Wal. 2020.: Projecting Antarctica's contribution to future sea level rise from basal ice shelf melt using linear response functions of 16 ice sheet models (LARMIP-2).
Earth System Dynamics 11 (1), 35-76. DOI
Logan, L. C., S. H. K. Narayanan, R. Greve and P. Heimbach. 2020.: SICOPOLIS-AD v1: an open-source adjoint modeling framework for ice sheet simulation enabled by the algorithmic differentiation tool OpenAD.
Geoscientific Model Development 13 (4), 1845-1864. DOI
Robinson, A., J. Alvarez-Solas, M. Montoya, H. Goelzer, R. Greve and C. Ritz. 2020.: Description and validation of the ice-sheet model Yelmo (version 1.0).
Geoscientific Model Development 13 (6), 2805-2823. DOI
Seroussi, H., S. Nowicki, A. J. Payne, H. Goelzer, W. H. Lipscomb, A. Abe-Ouchi, C. Agosta, T. Albrecht, X. Asay-Davis, A. Barthel, R. Calov, R. Cullather, C. Dumas, B. K. Galton-Fenzi, R. Gladstone, N. Golledge, J. M. Gregory, R. Greve, T. Hatterman, M. J. Hoffman, A. Humbert, P. Huybrechts, N. C. Jourdain, T. Kleiner, E. Larour, G. R. Leguy, D. P. Lowry, C. M. Little, M. Morlighem, F. Pattyn, T. Pelle, S. F. Price, A. Quiquet, R. Reese, N.-J. Schlegel, A. Shepherd, E. Simon, R. S. Smith, F. Straneo, S. Sun, L. D. Trusel, J. Van Breedam, R. S. W. van de Wal, R. Winkelmann, C. Zhao, T. Zhang and T. Zwinger. 2020.: ISMIP6 Antarctica: a multi-model ensemble of the Antarctic ice sheet evolution over the 21st century.
The Cryosphere 14 (9), 3033-3070. DOI
Sun, S., F. Pattyn, E. G. Simon, T. Albrecht, S. Cornford, R. Calov, C. Dumas, F. Gillet-Chaulet, H. Goelzer, N. R. Golledge, R. Greve, M. J. Hoffman, A. Humbert, E. Kazmierczak, T. Kleiner, G. R. Leguy, W. H. Lipscomb, D. Martin, M. Morlighem, S. Nowicki, D. Pollard, S. Price, A. Quiquet, H. Seroussi, T. Schlemm, J. Sutter, R. S. W. van de Wal, R. Winkelmann and T. Zhang. 2020.: Antarctic ice sheet response to sudden and sustained ice-shelf collapse (ABUMIP).
Journal of Glaciology 66 (260), 891-904. DOI
Wunderling, N., M. Willeit, J. F. Donges and R. Winkelmann. 2020.: Global warming due to loss of large ice masses and Arctic summer sea ice.
Nature Communications 11 (1), 5177. DOI

2019

Beckmann, J., M. Perrette, S. Beyer, R. Calov, M. Willeit and A. Ganopolski. 2019.: Modeling the response of Greenland outlet glaciers to global warming using a coupled flow line-plume model.
The Cryosphere 13 (9), 2281-2301. DOI
Greve, R. 2019.: Geothermal heat flux distribution for the Greenland ice sheet, derived by combining a global representation and information from deep ice cores.
Polar Data Journal 3, 22-36. DOI
Nordhaus, W. 2019.: Economics of the disintegration of the Greenland ice sheet.
Proceedings of the National Academy of Sciences 116 (25), 12261-12269. DOI
Rezvanbehbahani, S., L. A. Stearns, C. J. van der Veen, G. K. A. Oswald and R. Greve. 2019.: Constraining the geothermal heat flux in Greenland at regions of radar-detected basal water.
Journal of Glaciology 65 (254), 1023-1034. DOI
Rückamp, M., R. Greve and A. Humbert. 2019.: Comparative simulations of the evolution of the Greenland ice sheet under simplified Paris Agreement scenarios with the models SICOPOLIS and ISSM.
Polar Science 21, 14-25. DOI
Seroussi, H., S. Nowicki, E. Simon, A. Abe-Ouchi, T. Albrecht, J. Brondex, S. Cornford, C. Dumas, F. Gillet-Chaulet, H. Goelzer, N. R. Golledge, J. M. Gregory, R. Greve, M. J. Hoffman, A. Humbert, P. Huybrechts, T. Kleiner, E. Larour, G. Leguy, W. H. Lipscomb, D. Lowry, M. Mengel, M. Morlighem, F. Pattyn, A. J. Payne, D. Pollard, S. F. Price, A. Quiquet, T. J. Reerink, R. Reese, C. B. Rodehacke, N.-J. Schlegel, A. Shepherd, S. Sun, J. Sutter, J. Van Breedam, R. S. W. van de Wal, R. Winkelmann and T. Zhang. 2019.: InitMIP-Antarctica: an ice sheet model initialization experiment of ISMIP6.
The Cryosphere 13 (5), 1441-1471. DOI
Willeit, M., A. Ganopolski, R. Calov and V. Brovkin. 2019.: Mid-Pleistocene transition in glacial cycles explained by declining CO₂ and regolith removal.
Science Advances 5 (4), eaav7337. DOI

2018

Calov, R., S. Beyer, R. Greve, J. Beckmann, M. Willeit, T. Kleiner, M. Rückamp, A. Humbert and A. Ganopolski. 2018.: Simulation of the future sea level contribution of Greenland with a new glacial system model.
The Cryosphere 12 (10), 3097-3121. DOI
Dolan, A. M., B. de Boer, J. Bernales, D. J. Hill and A. M. Haywood. 2018.: High climate model dependency of Pliocene Antarctic ice-sheet predictions.
Nature Communications 9, 2799. DOI
Goelzer, H., S. Nowicki, T. Edwards, M. Beckley, A. Abe-Ouchi, A. Aschwanden, R. Calov, O. Gagliardini, F. Gillet-Chaulet, N. R. Golledge, J. Gregory, R. Greve, A. Humbert, P. Huybrechts, J. H. Kennedy, E. Larour, W. H. Lipscomb, S. Le clec'h, V. Lee, M. Morlighem, F. Pattyn, A. J. Payne, C. Rodehacke, M. Rückamp, F. Saito, N. Schlegel, H. Seroussi, A. Shepherd, S. Sun, R. van de Wal and F. A. Ziemen. 2018.: Design and results of the ice sheet model initialisation experiments initMIP-Greenland: an ISMIP6 intercomparison.
The Cryosphere 12 (4), 1433-1460. DOI
Le Bars, D. 2018.: Uncertainty in sea level rise projections due to the dependence between contributors.
Earth's Future 6 (9), 1275-1291. DOI
Lofverstrom, M. and J. Liakka. 2018.: The influence of atmospheric grid resolution in a climate model-forced ice sheet simulation.
The Cryosphere 12 (4), 1499-1510. DOI
Olson, R., K. L. Ruckert, W. Chang, K. Keller, M. Haran and S.-I. An. 2018.: Stilt: Easy emulation of time series AR(1) computer model output in multidimensional parameter space.
The R Journal 10 (2), 209-225. DOI
Oswald, G. K. A., S. Rezvanbehbahani and L. A. Stearns. 2018.: Radar evidence of ponded subglacial water in Greenland.
Journal of Glaciology 64 (247), 711-729. DOI
Willeit, M. and A. Ganopolski. 2018.: The importance of snow albedo for ice sheet evolution over the last glacial cycle.
Climate of the Past 14 (5), 697-707. DOI

2017

Bauer, E. and A. Ganopolski. 2017.: Comparison of surface mass balance of ice sheets simulated by positive-degree-day method and energy balance approach.
Climate of the Past 13 (7), 819-832. DOI
Bernales, J., I. Rogozhina, R. Greve and M. Thomas. 2017a.: Comparison of hybrid schemes for the combination of shallow approximations in numerical simulations of the Antarctic Ice Sheet.
The Cryosphere 11 (1), 247-265. DOI
Bernales, J., I. Rogozhina and M. Thomas. 2017b.: Melting and freezing under Antarctic ice shelves from a combination of ice-sheet modelling and observations.
Journal of Glaciology 63 (240), 731-744. DOI
Ganopolski, A. and V. Brovkin. 2017.: Simulation of climate, ice sheets and CO₂ evolution during the last four glacial cycles with an Earth system model of intermediate complexity.
Climate of the Past 13 (12), 1695-1716. DOI
Gudlaugsson, E., A. Humbert, K. Andreassen, C. C. Clason, T. Kleiner and S. Beyer. 2017.: Eurasian ice-sheet dynamics and sensitivity to subglacial hydrology.
Journal of Glaciology 63 (239), 556-564. DOI
Larour, E., E. R. Ivins and S. Adhikari. 2017.: Should coastal planners have concern over where land ice is melting?
Science Advances 3 (11), e1700537. DOI
Robinson, A., J. Alvarez-Solas, R. Calov, A. Ganopolski and M. Montoya. 2017.: MIS-11 duration key to disappearance of the Greenland ice sheet.
Nature Communications 8, 16008. DOI

2016

Bakker, A. M. R., P. J. Applegate and K. Keller. 2016.: A simple, physically motivated model of sea-level contributions from the Greenland ice sheet in response to temperature changes.
Environmental Modelling & Software 83, 27-35. DOI
Clark, P. U., J. D. Shakun, S. A. Marcott, A. C. Mix, M. Eby, S. Kulp, A. Levermann, G. A. Milne, P. L. Pfister, B. D. Santer, D. P. Schrag, S. Solomon, T. F. Stocker, B. H. Strauss, A. J. Weaver, R. Winkelmann, D. Archer, E. Bard, A. Goldner, K. Lambeck, R. T. Pierrehumbert and G.-K. Plattner. 2016.: Consequences of twenty-first-century policy for multi-millennial climate and sea-level change.
Nature Climate Change 6 (4), 360–369. DOI
Ganopolski, A., R. Winkelmann and H. J. Schellnhuber. 2016.: Critical insolation–CO₂ relation for diagnosing past and future glacial inception.
Nature 529 (7585), 200-203. DOI
Greve, R. and H. Blatter. 2016.: Comparison of thermodynamics solvers in the polythermal ice sheet model SICOPOLIS.
Polar Science 10 (1), 11-23. DOI
Jordan, T. M., J. L. Bamber, C. N. Williams, J. D. Paden, M. J. Siegert, P. Huybrechts, O. Gagliardini and F. Gillet-Chaulet. 2016.: An ice-sheet-wide framework for englacial attenuation from ice-penetrating radar data.
The Cryosphere 10 (4), 1547-1570. DOI
Liakka, J., M. Löfverström and F. Colleoni. 2016.: The impact of the North American glacial topography on the evolution of the Eurasian ice sheet over the last glacial cycle.
Climate of the Past 12 (5), 1225-1241. DOI
MacGregor, J. A., M. A. Fahnestock, G. A. Catania, A. Aschwanden, G. D. Clow, W. T. Colgan, S. P. Gogineni, M. Morlighem, S. M. J. Nowicki, J. D. Paden, S. F. Price and H. Seroussi. 2016.: A synthesis of the basal thermal state of the Greenland Ice Sheet.
Journal of Geophysical Research: Earth Surface 121 (7), 1328-1350. DOI
Rogozhina, I., A. G. Petrunin, A. P. M. Vaughan, B. Steinberger, J. V. Johnson, M. K. Kaban, R. Calov, F. Rickers, M. Thomas and I. Koulakov. 2016.: Melting at the base of the Greenland ice sheet explained by Iceland hotspot history.
Nature Geoscience 9 (5), 366-369. DOI
Yau, A. M., M. L. Bendera, A. Robinson and E. J. Brook. 2016.: Reconstructing the last interglacial at Summit, Greenland: Insights from GISP2.
Proceedings of the National Academy of Sciences 113 (35), 9710-9715. DOI

2015

Applegate, P. J. and K. Keller. 2015.: How effective is albedo modification (solar radiation management geoengineering) in preventing sea-level rise from the Greenland Ice Sheet?
Environmental Research Letters 10 (8), 084018. DOI
Applegate, P. J., B. R. Parizek, R. E. Nicholas, R. B. Alley and K. Keller. 2015.: Increasing temperature forcing reduces the Greenland Ice Sheet's response time scale.
Climate Dynamics 45 (7), 2001-2011. DOI
Calov, R., A. Robinson, M. Perrette and A. Ganopolski. 2015.: Simulating the Greenland ice sheet under present-day and palaeo constraints including a new discharge parameterization.
The Cryosphere 9 (1), 179-196. DOI
De Boer, B., A. M. Dolan, J. Bernales, E. Gasson, H. Goelzer, N. R. Golledge, J. Sutter, P. Huybrechts, G. Lohmann, I. Rogozhina, A. Abe-Ouchi, F. Saito and R. S. W. van de Wal. 2015.: Simulating the Antarctic ice sheet in the late-Pliocene warm period: PLISMIP-ANT, an ice-sheet model intercomparison project.
The Cryosphere 9 (3), 881-903. DOI
Kusahara, K., T. Sato, A. Oka, T. Obase, R. Greve, A. Abe-Ouchi and H. Hasumi. 2015.: Modelling the Antarctic marine cryosphere at the Last Glacial Maximum.
Annals of Glaciology 56 (69), 425-435. DOI
Löfverström, M., J. Liakka and J. Kleman. 2015.: The North American Cordillera—An impediment to growing the continent-wide Laurentide ice sheet.
Journal of Climate 28 (23), 9433-9450. DOI
Tallavaaraa, M., M. Luoto, N. Korhonen, H. Järvinen and H. Seppä. 2015.: Human population dynamics in Europe over the Last Glacial Maximum.
Proceedings of the National Academy of Sciences 112 (27), 8232-8237. DOI
Vizcaíno, M., U. Mikolajewicz, F. Ziemen, C. B. Rodehacke, R. Greve and M. R. van den Broeke. 2015.: Coupled simulations of Greenland Ice Sheet and climate change up to A.D. 2300.
Geophysical Research Letters 42 (10), 3927-3935. DOI
Willeit, M. and A. Ganopolski. 2015.: Coupled Northern Hemisphere permafrost-ice-sheet evolution over the last glacial cycle.
Climate of the Past 11 (9), 1165-1180. DOI
Willeit, M., A. Ganopolski, R. Calov, A. Robinson and M. Maslin. 2015.: The role of CO₂ decline for the onset of Northern Hemisphere glaciation.
Quaternary Science Reviews 119, 22-34. DOI

2014

Chang, W., P. J. Applegate, M. Haran and K. Keller. 2014.: Probabilistic calibration of a Greenland Ice Sheet model using spatially resolved synthetic observations: toward projections of ice mass loss with uncertainties.
Geoscientific Model Development 7 (5), 1933-1943. DOI
Clason, C. C., P. J. Applegate and P. Holmlund. 2014.: Modelling Late Weichselian evolution of the Eurasian ice sheets forced by surface meltwater-enhanced basal sliding.
Journal of Glaciology 60 (219), 29-40. DOI
Edwards, T. L., X. Fettweis, O. Gagliardini, F. Gillet-Chaulet, H. Goelzer, J. M. Gregory, M. Hoffman, P. Huybrechts, A. J. Payne, M. Perego, S. Price, A. Quiquet and C. Ritz. 2014.: Effect of uncertainty in surface mass balance–elevation feedback on projections of the future sea level contribution of the Greenland ice sheet.
The Cryosphere 8 (1), 195-208. DOI
Goelles, T., K. Grosfeld and G. Lohmann. 2014.: Semi-Lagrangian transport of oxygen isotopes in polythermal ice sheets: implementation and first results.
Geoscientific Model Development 7 (4), 1395-1408. DOI
Korhonen, N., A. Venäläinen, H. Seppä and H. Järvinen. 2014.: Statistical downscaling of a climate simulation of the last glacial cycle: temperature and precipitation over Northern Europe.
Climate of the Past 10 (4), 1489-1500. DOI
Levermann, A., R. Winkelmann, S. Nowicki, J. L. Fastook, K. Frieler, R. Greve, H. H. Hellmer, M. A. Martin, M. Meinshausen, M. Mengel, A. J. Payne, D. Pollard, T. Sato, R. Timmermann, W. L. Wang and R. A. Bindschadler. 2014.: Projecting Antarctic ice discharge using response functions from SeaRISE ice-sheet models.
Earth System Dynamics 5 (2), 271-293. DOI
Liakka, J., F. Colleoni, B. Ahrens and T. Hickler. 2014.: The impact of climate-vegetation interactions on the onset of the Antarctic ice sheet.
Geophysical Research Letters 41 (4), 1269-1276. DOI
Robinson, A. and H. Goelzer. 2014.: The importance of insolation changes for paleo ice sheet modeling.
The Cryosphere 8 (4), 1419-1428. DOI
Rogozhina, I. and D. Rau. 2014.: Vital role of daily temperature variability in surface mass balance parameterizations of the Greenland Ice Sheet.
The Cryosphere 8 (2), 575-585. DOI
Yan, Q., H. Wang, O. M. Johannessen and Z. Zhang. 2014.: Greenland ice sheet contribution to future global sea level rise based on CMIP5 models.
Advances in Atmospheric Sciences 31 (1), 8-16. DOI
Yan, Q., Z. Zhang, H. Wang and R. Zhang. 2014.: Simulation of Greenland ice sheet during the mid-Pliocene warm period.
Chinese Science Bulletin 59 (2), 201-211. DOI

2013

Bindschadler, R. A., S. Nowicki, A. Abe-Ouchi, A. Aschwanden, H. Choi, J. Fastook, G. Granzow, R. Greve, G. Gutowski, U. C. Herzfeld, C. Jackson, J. Johnson, C. Khroulev, A. Levermann, W. H. Lipscomb, M. A. Martin, M. Morlighem, B. R. Parizek, D. Pollard, S. F. Price, D. Ren, F. Saito, T. Sato, H. Seddik, H. Seroussi, K. Takahashi, R. Walker and W. L. Wang. 2013.: Ice-sheet model sensitivities to environmental forcing and their use in projecting future sea level (the SeaRISE project).
Journal of Glaciology 59 (214), 195-224. DOI
Greve, R. and U. C. Herzfeld. 2013.: Resolution of ice streams and outlet glaciers in large-scale simulations of the Greenland ice sheet.
Annals of Glaciology 54 (63), 209-220. DOI
Nowicki, S., R. A. Bindschadler, A. Abe-Ouchi, A. Aschwanden, E. Bueler, H. Choi, J. Fastook, G. Granzow, R. Greve, G. Gutowski, U. C. Herzfeld, C. Jackson, J. Johnson, C. Khroulev, E. Larour, A. Levermann, W. H. Lipscomb, M. A. Martin, M. Morlighem, B. R. Parizek, D. Pollard, S. F. Price, D. Ren, E. Rignot, F. Saito, T. Sato, H. Seddik, H. Seroussi, K. Takahashi, R. Walker and W. L. Wang. 2013a.: Insights into spatial sensitivities of ice mass response to environmental change from the SeaRISE ice sheet modeling project I: Antarctica.
Journal of Geophysical Research: Earth Surface 118 (2), 1002-1024. DOI
Nowicki, S., R. A. Bindschadler, A. Abe-Ouchi, A. Aschwanden, E. Bueler, H. Choi, J. Fastook, G. Granzow, R. Greve, G. Gutowski, U. C. Herzfeld, C. Jackson, J. Johnson, C. Khroulev, E. Larour, A. Levermann, W. H. Lipscomb, M. A. Martin, M. Morlighem, B. R. Parizek, D. Pollard, S. F. Price, D. Ren, E. Rignot, F. Saito, T. Sato, H. Seddik, H. Seroussi, K. Takahashi, R. Walker and W. L. Wang. 2013b.: Insights into spatial sensitivities of ice mass response to environmental change from the SeaRISE ice sheet modeling project II: Greenland.
Journal of Geophysical Research: Earth Surface 118 (2), 1025-1044. DOI
Petrunin, A., I. Rogozhina, A. P. M. Vaughan, I. T. Kukkonen, M. Kaban, I. Koulakov and M. Thomas. 2013.: Heat flux variations beneath central Greenland's ice due to anomalously thin lithosphere.
Nature Geoscience 6 (9), 746-750. DOI
Willeit, M., A. Ganopolski and G. Feulner. 2013.: On the effect of orbital forcing on mid-Pliocene climate, vegetation and ice sheets.
Climate of the Past 9 (4), 1749-1759. DOI
Yan, Q., Z. Zhang, Y. Gao, H. Wang and O. M. Johannessen. 2013.: Sensitivity of the modeled present-day Greenland Ice Sheet to climatic forcing and spin-up methods and its influence on future sea level projections.
Journal of Geophysical Research: Earth Surface 118 (4), 2174-2189. DOI

2012

Applegate, P. J., N. Kirchner, E. J. Stone, K. Keller and R. Greve. 2012.: An assessment of key model parametric uncertainties in projections of Greenland Ice Sheet behavior.
The Cryosphere 6 (3), 589-606. DOI
Born, A. and K. H. Nisancioglu. 2012.: Melting of Northern Greenland during the last interglaciation.
The Cryosphere 6 (6), 1239-1250. DOI
Brovkin, V., A. Ganopolski, D. Archer and G. Munhoven. 2012.: Glacial CO₂ cycle as a succession of key physical and biogeochemical processes.
Climate of the Past 8 (1), 251-264. DOI
Gillet-Chaulet, F., O. Gagliardini, H. Seddik, M. Nodet, G. Durand, C. Ritz, T. Zwinger, R. Greve and D. G. Vaughan. 2012.: Greenland ice sheet contribution to sea-level rise from a new-generation ice-sheet model.
The Cryosphere 6 (6), 1561-1576. DOI
Herzfeld, U. C., J. L. Fastook, R. Greve, B. McDonald, B. F. Wallin and P. A. Chen. 2012.: On the influence of Greenland outlet glacier bed topography on results from dynamic ice-sheet models.
Annals of Glaciology 53 (60), 281-293. DOI
Liakka, J. 2012.: Interactions between topographically and thermally forced stationary waves: implications for ice-sheet evolution.
Tellus A 64, 11088. DOI
Liakka, J., J. Nilsson and M. Löfverström. 2012.: Interactions between stationary waves and ice sheets: linear versus nonlinear atmospheric response.
Climate Dynamics 38 (5-6), 1249-1262. DOI
Robinson, A., R. Calov and A. Ganopolski. 2012.: Multistability and critical thresholds of the Greenland ice sheet.
Nature Climate Change 2 (6), 429-432. DOI
Rogozhina, I., J. M. Hagedoorn, Z. Martinec, K. Fleming, O. Soucek, R. Greve and M. Thomas. 2012.: Effects of uncertainties in the geothermal heat flux distribution on the Greenland Ice Sheet: An assessment of existing heat flow models.
Journal of Geophysical Research: Earth Surface 117 (F2), F02025. DOI
Sato, T. and R. Greve. 2012.: Sensitivity experiments for the Antarctic ice sheet with varied sub-ice-shelf melting rates.
Annals of Glaciology 53 (60), 221-228. DOI
Seddik, H., R. Greve, T. Zwinger, F. Gillet-Chaulet and O. Gagliardini. 2012.: Simulations of the Greenland ice sheet 100 years into the future with the full Stokes model Elmer/Ice.
Journal of Glaciology 58 (209), 427-440. DOI

2011

Dunse, T., R. Greve, T. V. Schuler and J. O. Hagen. 2011.: Permanent fast flow versus cyclic surge behaviour: numerical simulations of the Austfonna ice cap, Svalbard.
Journal of Glaciology 57 (202), 247-259. DOI
Ganopolski, A. and R. Calov. 2011.: The role of orbital forcing, carbon dioxide and regolith in 100 kyr glacial cycles.
Climate of the Past 7 (4), 1415-1425. DOI
Greve, R., F. Saito and A. Abe-Ouchi. 2011.: Initial results of the SeaRISE numerical experiments with the models SICOPOLIS and IcIES for the Greenland ice sheet.
Annals of Glaciology 52 (58), 23-30. DOI
Kirchner, N., R. Greve, A. P. Stroeven and J. Heyman. 2011.: Paleoglaciological reconstructions for the Tibetan Plateau during the last glacial cycle: evaluating numerical ice sheet simulations driven by GCM-ensembles.
Quaternary Science Reviews 30 (1-2), 248-267. DOI
Ren, D., R. Fu, L. M. Leslie, D. J. Karoly, J. Chen and C. R. Wilson. 2011.: A multirheology ice model: Formulation and application to the Greenland ice sheet.
Journal of Geophysical Research: Atmospheres 116 (D5), D05112. DOI
Ren, D., R. Fu, L. M. Leslie, J. Chen, C. R. Wilson and D. J. Karoly. 2011.: The Greenland ice sheet response to transient climate change.
Journal of Climate 24 (13), 3469-3483. DOI
Robinson, A., R. Calov and A. Ganopolski. 2011.: Greenland ice sheet model parameters constrained using simulations of the Eemian Interglacial.
Climate of the Past 7 (2), 381-396. DOI
Rogozhina, I., Z. Martinec, J. M. Hagedoorn, M. Thomas and K. Fleming. 2011.: On the long-term memory of the Greenland Ice Sheet.
Journal of Geophysical Research: Earth Surface 116 (F1), F01011. DOI

2010

Born, A., M. Kageyama and K. H. Nisancioglu. 2010.: Warm Nordic Seas delayed glacial inception in Scandinavia.
Climate of the Past 6 (6), 817-826. DOI
Calov, R., R. Greve, A. Abe-Ouchi, E. Bueler, P. Huybrechts, J. V. Johnson, F. Pattyn, D. Pollard, C. Ritz, F. Saito and L. Tarasov. 2010.: Results from the Ice-Sheet Model Intercomparison Project - Heinrich Event INtercOmparison (ISMIP HEINO).
Journal of Glaciology 56 (197), 371-383. DOI
Ganopolski, A., R. Calov and M. Claussen. 2010.: Simulation of the last glacial cycle with a coupled climate ice-sheet model of intermediate complexity.
Climate of the Past 6 (2), 229-244. DOI
Iizuka, Y., H. Miura, S. Iwasaki, H. Maemoku, T. Sawagaki, R. Greve, H. Satake, K. Sasa and Y. Matsushi. 2010.: Evidence of past migration of the ice divide between the Shirase and Sôya drainage basins derived from chemical characteristics of the marginal ice in the Sôya drainage basin, East Antarctica.
Journal of Glaciology 56 (197), 395-404. DOI
Ren, D., R. Fu, D. J. Karoly, L. M. Leslie, J. Chen and C. R. Wilson. 2010.: A new ice sheet model validated by remote sensing of the Greenland ice sheet.
Central European Journal of Geosciences 2 (4), 501-513. DOI
Robinson, A., R. Calov and A. Ganopolski. 2010.: An efficient regional energy-moisture balance model for simulation of the Greenland Ice Sheet response to climate change.
The Cryosphere 4 (2), 129-144. DOI
Vizcaíno, M., U. Mikolajewicz, J. Jungclaus and G. Schurgers. 2010.: Climate modification by future ice sheet changes and consequences for ice sheet mass balance.
Climate Dynamics 34 (2-3), 301-324. DOI

2009

Calov, R., A. Ganopolski, C. Kubatzki and M. Claussen. 2009.: Mechanisms and time scales of glacial inception simulated with an Earth system model of intermediate complexity.
Climate of the Past 5 (2), 245-258. DOI
Heimbach, P. and V. Bugnion. 2009.: Greenland ice-sheet volume sensitivity to basal, surface and initial conditions derived from an adjoint model.
Annals of Glaciology 50 (52), 67-80. DOI
Vinther, B. M., S. L. Buchardt, H. B. Clausen, D. Dahl-Jensen, S. J. Johnsen, D. A. Fisher, R. M. Koerner, D. Raynaud, V. Lipenkov, K. K. Andersen, T. Blunier, S. O. Rasmussen, J. P. Steffensen and A. M. Svensson. 2009.: Holocene thinning of the Greenland ice sheet.
Nature 461 (7262), 385-388. DOI

2008

Buchardt, S. L. and D. Dahl-Jensen 2008.: At what depth is the Eemian layer expected to be found at NEEM?
Annals of Glaciology 48, 100-102. DOI
Greve, R. 2008.: Scenarios for the formation of Chasma Boreale, Mars.
Icarus 196 (2), 359-367. DOI
Vizcaíno, M., U. Mikolajewicz, M. Gröger, E. Maier-Reimer, G. Schurgers and A. M. E. Winguth. 2008.: Long-term ice sheet-climate interactions under anthropogenic greenhouse forcing simulated with a complex Earth System Model.
Climate Dynamics 31 (6), 665-690. DOI

2007

Mikolajewicz, U., M. Gröger, E. Maier-Reimer, G. Schurgers, M. Vizcaíno and A. M. E. Winguth. 2007.: Long-term effects of anthropogenic CO₂ emissions simulated with a complex earth system model.
Climate Dynamics 28 (6), 599-633. DOI
Mikolajewicz, U., M. Vizcaíno, J. Jungclaus and G. Schurgers. 2007.: Effect of ice sheet interactions in anthropogenic climate change simulations.
Geophysical Research Letters 34 (18), L18706. DOI
Stenzel, O. J., B. Grieger, H. U. Keller, R. Greve, K. Fraedrich, E. Kirk and F. Lunkeit. 2007.: Coupling Planet Simulator Mars, a general circulation model of the Martian atmosphere, to the ice sheet model SICOPOLIS.
Planetary and Space Science 55 (14), 2087-2096. DOI

2006

Calov, R. 2006.: Modelling of terrestrial ice sheets in palaeo-climate research.
GAMM-Mitteilungen 29 (1), 9-28. DOI
Greve, R. 2006.: Fluid dynamics of planetary ices.
GAMM-Mitteilungen 29 (1), 29-51. DOI
Greve, R., R. Takahama and R. Calov. 2006.: Simulation of large-scale ice-sheet surges: The ISMIP HEINO experiments.
Polar Meteorology and Glaciology 20, 1-15. HUSCAP

2005

Calov, R. and A. Ganopolski. 2005.: Multistability and hysteresis in the climate-cryosphere system under orbital forcing.
Geophysical Research Letters 32 (21), L21717. DOI
Calov, R., A. Ganopolski, M. Claussen, V. Petoukhov and R. Greve. 2005.: Transient simulation of the last glacial inception. Part I: Glacial inception as a bifurcation in the climate system.
Climate Dynamics 24 (6), 545-561. DOI
Calov, R., A. Ganopolski, V. Petoukhov, M. Claussen, V. Brovkin and C. Kubatzki. 2005.: Transient simulation of the last glacial inception. Part II: Sensitivity and feedback analysis.
Climate Dynamics 24 (6), 563-576. DOI
Greve, R. 2005.: Relation of measured basal temperatures and the spatial distribution of the geothermal heat flux for the Greenland ice sheet.
Annals of Glaciology 42, 424-432. DOI
Greve, R. and R. A. Mahajan. 2005.: Influence of ice rheology and dust content on the dynamics of the north-polar cap of Mars.
Icarus 174 (2), 475-485. DOI
Winguth, A., U. Mikolajewicz, M. Gröger, E. Maier-Reimer, G. Schurgers and M. Vizcaíno. 2005.: Centennial-scale interactions between the carbon cycle and anthropogenic climate change using a dynamic Earth system model.
Geophysical Research Letters 32 (23), L23714. DOI

2004

Forsström, P.-L. and R. Greve. 2004.: Simulation of the Eurasian ice sheet dynamics during the last glaciation.
Global and Planetary Change 42 (1-4), 59-81. DOI
Greve, R., R. A. Mahajan, J. Segschneider and B. Grieger. 2004.: Evolution of the north-polar cap of Mars: a modelling study.
Planetary and Space Science 52 (9), 775-787. DOI

2003

Forsström, P.-L., O. Sallasmaa, R. Greve and T. Zwinger. 2003.: Simulation of fast-flow features of the Fennoscandian ice sheet during the Last Glacial Maximum.
Annals of Glaciology 37, 383-389. DOI
Greve, R., V. Klemann and D. Wolf. 2003.: Ice flow and isostasy of the north polar cap of Mars.
Planetary and Space Science 51 (3), 193-204. DOI

2002

Calov, R., A. Ganopolski, V. Petoukhov, M. Claussen and R. Greve. 2002.: Large-scale instabilities of the Laurentide ice sheet simulated in a fully coupled climate-system model.
Geophysical Research Letters 29 (24), 2216. DOI
Greve, R. and R. Calov. 2002.: Comparison of numerical schemes for the solution of the ice-thickness equation in a dynamic/thermodynamic ice-sheet model.
Journal of Computational Physics 179 (2), 649-664. DOI
Roe, G. H. 2002.: Modeling precipitation over ice sheets: an assessment using Greenland.
Journal of Glaciology 48 (160), 70-80. DOI

2001

Baral, D. R., K. Hutter and R. Greve. 2001.: Asymptotic theories of large-scale motion, temperature, and moisture distribution in land-based polythermal ice sheets: A critical review and new developments.
Applied Mechanics Reviews 54 (3), 215-256. DOI
Roe, G. H. and R. S. Lindzen. 2001.: The mutual interaction between continental-scale ice sheets and atmospheric stationary waves.
Journal of Climate 14 (7), 1450-1465. DOI

2000

Greve, R. 2000a.: On the response of the Greenland ice sheet to greenhouse climate change.
Climatic Change 46 (3), 289-303. DOI
Greve, R. 2000b.: Waxing and waning of the perennial north polar H2O ice cap of Mars over obliquity cycles.
Icarus 144 (2), 419-431. DOI
Payne, A. J., P. Huybrechts, A. Abe-Ouchi, R. Calov, J. L. Fastook, R. Greve, S. J. Marshall, I. Marsiat, C. Ritz, L. Tarasov and M. P. A. Thomassen. 2000.: Results from the EISMINT model intercomparison: the effects of thermomechanical coupling.
Journal of Glaciology 46 (153), 227-238. DOI
Savvin, A. A., R. Greve, R. Calov, B. Mügge and K. Hutter. 2000.: Simulation of the Antarctic ice sheet with a three-dimensional polythermal ice-sheet model, in support of the EPICA project. II. Nested high-resolution treatment of Dronning Maud Land, Antarctica.
Annals of Glaciology 30, 69-75. DOI

1999

Greve, R., K.-H. Wyrwoll and A. Eisenhauer. 1999.: Deglaciation of the Northern Hemisphere at the onset of the Eemian and Holocene.
Annals of Glaciology 28, 1-8. DOI

1998

Calov, R., A. A. Savvin, R. Greve, I. Hansen and K. Hutter. 1998.: Simulation of the Antarctic ice sheet with a three-dimensional polythermal ice-sheet model, in support of the EPICA project.
Annals of Glaciology 27, 201-206. HUSCAP
Greve, R., M. Weis and K. Hutter. 1998.: Palaeoclimatic evolution and present conditions of the Greenland ice sheet in the vicinity of Summit: An approach by large-scale modelling.
Paleoclimates: Data and Modelling 2 (2-3), 133-161. HUSCAP

1997

Greve, R. 1997a.: A continuum-mechanical formulation for shallow polythermal ice sheets.
Philosophical Transactions of the Royal Society A 355 (1726), 921-974. DOI
Greve, R. 1997b.: Application of a polythermal three-dimensional ice sheet model to the Greenland ice sheet: Response to steady-state and transient climate scenarios.
Journal of Climate 10 (5), 901-918. DOI
Greve, R. 1997c.: Large-scale ice-sheet modelling as a means of dating deep ice cores in Greenland.
Journal of Glaciology 43 (144), 307-310. Erratum: 43 (145), 597-600. HUSCAP

1996

Greve, R. and D. R. MacAyeal. 1996.: Dynamic/thermodynamic simulations of Laurentide ice-sheet instability.
Annals of Glaciology 23, 328-335. HUSCAP
Hansen, I. and R. Greve. 1996.: Polythermal modelling of steady states of the Antarctic ice sheet in comparison with the real world.
Annals of Glaciology 23, 382-387. HUSCAP
Huybrechts, P., A. J. Payne and the EISMINT Intercomparison Group. 1996.: The EISMINT benchmarks for testing ice-sheet models.
Annals of Glaciology 23, 1-12. HUSCAP
Van Tatenhove, F. G. M., A. Fabré, R. Greve and P. Huybrechts. 1996.: Modelled ice-sheet margins of three Greenland ice-sheet models compared with a geological record from ice-marginal deposits in central West Greenland.
Annals of Glaciology 23, 52-58. HUSCAP

1995

Greve, R. and K. Hutter. 1995.: Polythermal three-dimensional modelling of the Greenland ice sheet with varied geothermal heat flux.
Annals of Glaciology 21, 8-12. HUSCAP

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