TY - JOUR
T1 - Grounding-line migration in plan-view marine ice-sheet models
T2 - Results of the ice2sea MISMIP3d intercomparison
AU - Pattyn, Frank
AU - Perichon, Laura
AU - Durand, Gaël
AU - Favier, Lionel
AU - Gagliardini, Olivier
AU - Hindmarsh, Richard C.A.
AU - Zwinger, Thomas
AU - Albrecht, Torsten
AU - Cornford, Stephen
AU - Docquier, David
AU - Fürst, Johannes J.
AU - Goldberg, Daniel
AU - Gudmundsson, G. Hilmar
AU - Humbert, Angelika
AU - Hütten, Moritz
AU - Huybrechts, Philippe
AU - Jouvet, Guillaume
AU - Kleiner, Thomas
AU - Larour, Eric
AU - Martin, Daniel
AU - Morlighem, Mathieu
AU - Payne, Anthony J.
AU - Pollard, David
AU - Rückamp, Martin
AU - Rybak, Oleg
AU - Seroussi, Hélène
AU - Thoma, Malte
AU - Wilkens, Nina
PY - 2013/7
Y1 - 2013/7
N2 - Predictions of marine ice-sheet behaviour require models able to simulate grounding-line migration. We present results of an intercomparison experiment for plan-view marine ice-sheet models. Verification is effected by comparison with approximate analytical solutions for flux across the grounding line using simplified geometrical configurations (no lateral variations, no buttressing effects from lateral drag). Perturbation experiments specifying spatial variation in basal sliding parameters permitted the evolution of curved grounding lines, generating buttressing effects. The experiments showed regions of compression and extensional flow across the grounding line, thereby invalidating the boundary layer theory. Steady-state grounding-line positions were found to be dependent on the level of physical model approximation. Resolving grounding lines requires inclusion of membrane stresses, a sufficiently small grid size (>500 m), or subgrid interpolation of the grounding line. The latter still requires nominal grid sizes of >5 km. For larger grid spacings, appropriate parameterizations for ice flux may be imposed at the grounding line, but the short-time transient behaviour is then incorrect and different from models that do not incorporate grounding-line parameterizations. The numerical error associated with predicting grounding-line motion can be reduced significantly below the errors associated with parameter ignorance and uncertainties in future scenarios.
AB - Predictions of marine ice-sheet behaviour require models able to simulate grounding-line migration. We present results of an intercomparison experiment for plan-view marine ice-sheet models. Verification is effected by comparison with approximate analytical solutions for flux across the grounding line using simplified geometrical configurations (no lateral variations, no buttressing effects from lateral drag). Perturbation experiments specifying spatial variation in basal sliding parameters permitted the evolution of curved grounding lines, generating buttressing effects. The experiments showed regions of compression and extensional flow across the grounding line, thereby invalidating the boundary layer theory. Steady-state grounding-line positions were found to be dependent on the level of physical model approximation. Resolving grounding lines requires inclusion of membrane stresses, a sufficiently small grid size (>500 m), or subgrid interpolation of the grounding line. The latter still requires nominal grid sizes of >5 km. For larger grid spacings, appropriate parameterizations for ice flux may be imposed at the grounding line, but the short-time transient behaviour is then incorrect and different from models that do not incorporate grounding-line parameterizations. The numerical error associated with predicting grounding-line motion can be reduced significantly below the errors associated with parameter ignorance and uncertainties in future scenarios.
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U2 - 10.3189/2013JoG12J129
DO - 10.3189/2013JoG12J129
M3 - Article
AN - SCOPUS:84880410049
SN - 0022-1430
VL - 59
SP - 410
EP - 422
JO - Journal of Glaciology
JF - Journal of Glaciology
IS - 215
ER -