C. Mosbeux, L. Padman, E. Klein, P. Bromirski, H. Fricker
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We investigate this hypothesis using\nseveral time series of ice velocity from the Ross Ice Shelf (RIS),\nsatellite-based estimates of SSH seaward of the RIS front, ocean models of\nSSH under and near RIS, and a viscous ice sheet model. The observed annual\nchanges in RIS velocity are of the order of 1–10 m a−1 (roughly 1 % of\nmean flow). The ice sheet model, forced by the observed and modelled range\nof SSH of about 10 cm, reproduces the observed velocity changes when\nsufficiently large basal drag changes near the grounding line are\nparameterised. The model response is dominated by grounding line migration\nbut with a significant contribution from SSH-induced tilt of the ice shelf.\nWe expect that climate-driven changes in the seasonal cycles of winds and\nupper-ocean summer warming will modify the seasonal response of ice shelves\nto SSH and that nonlinear responses of the ice sheet will affect the longer\ntrend in ice sheet response and its potential sea-level rise contribution.\n","PeriodicalId":56315,"journal":{"name":"Cryosphere","volume":null,"pages":null},"PeriodicalIF":4.4000,"publicationDate":"2023-07-04","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":"{\"title\":\"Seasonal variability in Antarctic ice shelf velocities forced by sea surface height variations\",\"authors\":\"C. Mosbeux, L. Padman, E. Klein, P. Bromirski, H. Fricker\",\"doi\":\"10.5194/tc-17-2585-2023\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Abstract. Antarctica's ice shelves resist the flow of grounded ice towards\\nthe ocean through “buttressing” arising from their contact with ice rises,\\nrumples, and lateral margins. Ice shelf thinning and retreat reduce\\nbuttressing, leading to increased delivery of mass to the ocean that adds to\\nglobal sea level. Ice shelf response to large annual cycles in atmospheric\\nand oceanic processes provides opportunities to study the dynamics of both\\nice shelves and the buttressed grounded ice. Here, we explore whether\\nseasonal variability of sea surface height (SSH) can explain observed\\nseasonal variability of ice velocity. We investigate this hypothesis using\\nseveral time series of ice velocity from the Ross Ice Shelf (RIS),\\nsatellite-based estimates of SSH seaward of the RIS front, ocean models of\\nSSH under and near RIS, and a viscous ice sheet model. The observed annual\\nchanges in RIS velocity are of the order of 1–10 m a−1 (roughly 1 % of\\nmean flow). 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引用次数: 1
摘要
摘要南极洲的冰架通过与冰隆、褶皱和侧缘接触产生的“支撑”来抵抗搁浅的冰向海洋的流动。冰架变薄和退缩减少了吸引力,导致向海洋输送的质量增加,从而增加了全球海平面。冰架对大气和海洋过程中大的年周期的响应为研究冰架和支撑搁浅冰的动力学提供了机会。在这里,我们探讨了海面高度的季节变化是否可以解释观测到的冰速的季节变化。我们使用来自罗斯冰架(RIS)的几个冰速时间序列、基于卫星的RIS锋面SSH向海估计、RIS下和附近的SH海洋模型以及粘性冰盖模型来研究这一假设。观测到的RIS速度的年变化约为1-10 m a−1(大约1 % 曼流)。冰盖模型,由观测和建模的SSH范围约为10 cm再现了当接地线附近足够大的基础阻力变化被参数化时观察到的速度变化。模型响应主要由接地线迁移引起,但SSH引起的冰架倾斜对模型响应有显著影响。我们预计,气候驱动的风的季节性周期变化和上层海洋夏季变暖将改变冰架对SSH的季节性响应,而冰盖的非线性响应将影响冰盖响应的长期趋势及其潜在的海平面上升贡献。
Seasonal variability in Antarctic ice shelf velocities forced by sea surface height variations
Abstract. Antarctica's ice shelves resist the flow of grounded ice towards
the ocean through “buttressing” arising from their contact with ice rises,
rumples, and lateral margins. Ice shelf thinning and retreat reduce
buttressing, leading to increased delivery of mass to the ocean that adds to
global sea level. Ice shelf response to large annual cycles in atmospheric
and oceanic processes provides opportunities to study the dynamics of both
ice shelves and the buttressed grounded ice. Here, we explore whether
seasonal variability of sea surface height (SSH) can explain observed
seasonal variability of ice velocity. We investigate this hypothesis using
several time series of ice velocity from the Ross Ice Shelf (RIS),
satellite-based estimates of SSH seaward of the RIS front, ocean models of
SSH under and near RIS, and a viscous ice sheet model. The observed annual
changes in RIS velocity are of the order of 1–10 m a−1 (roughly 1 % of
mean flow). The ice sheet model, forced by the observed and modelled range
of SSH of about 10 cm, reproduces the observed velocity changes when
sufficiently large basal drag changes near the grounding line are
parameterised. The model response is dominated by grounding line migration
but with a significant contribution from SSH-induced tilt of the ice shelf.
We expect that climate-driven changes in the seasonal cycles of winds and
upper-ocean summer warming will modify the seasonal response of ice shelves
to SSH and that nonlinear responses of the ice sheet will affect the longer
trend in ice sheet response and its potential sea-level rise contribution.
期刊介绍:
The Cryosphere (TC) is a not-for-profit international scientific journal dedicated to the publication and discussion of research articles, short communications, and review papers on all aspects of frozen water and ground on Earth and on other planetary bodies.
The main subject areas are the following:
ice sheets and glaciers;
planetary ice bodies;
permafrost and seasonally frozen ground;
seasonal snow cover;
sea ice;
river and lake ice;
remote sensing, numerical modelling, in situ and laboratory studies of the above and including studies of the interaction of the cryosphere with the rest of the climate system.