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用于评估南极洲当前对海平面上升贡献的多变量时空建模。

Multivariate spatio-temporal modelling for assessing Antarctica's present-day contribution to sea-level rise.

作者信息

Zammit-Mangion Andrew, Rougier Jonathan, Schön Nana, Lindgren Finn, Bamber Jonathan

机构信息

School of Geographical Sciences, University of Bristol Bristol, BS8 1SS, U.K. ; Department of Mathematics, University of Bristol Bristol, BS8 1TW, U.K.

Department of Mathematics, University of Bristol Bristol, BS8 1TW, U.K.

出版信息

Environmetrics. 2015 May;26(3):159-177. doi: 10.1002/env.2323. Epub 2015 Jan 16.

DOI:10.1002/env.2323
PMID:25937792
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4413369/
Abstract

Antarctica is the world's largest fresh-water reservoir, with the potential to raise sea levels by about 60 m. An ice sheet contributes to sea-level rise (SLR) when its rate of ice discharge and/or surface melting exceeds accumulation through snowfall. Constraining the contribution of the ice sheets to present-day SLR is vital both for coastal development and planning, and climate projections. Information on various ice sheet processes is available from several remote sensing data sets, as well as data such as global positioning system data. These data have differing coverage, spatial support, temporal sampling and sensing characteristics, and thus, it is advantageous to combine them all in a single framework for estimation of the SLR contribution and the assessment of processes controlling mass exchange with the ocean. In this paper, we predict the rate of height change due to salient geophysical processes in Antarctica and use these to provide estimates of SLR contribution with associated uncertainties. We employ a multivariate spatio-temporal model, approximated as a Gaussian Markov random field, to take advantage of differing spatio-temporal properties of the processes to separate the causes of the observed change. The process parameters are estimated from geophysical models, while the remaining parameters are estimated using a Markov chain Monte Carlo scheme, designed to operate in a high-performance computing environment across multiple nodes. We validate our methods against a separate data set and compare the results to those from studies that invariably employ numerical model outputs directly. We conclude that it is possible, and insightful, to assess Antarctica's contribution without explicit use of numerical models. Further, the results obtained here can be used to test the geophysical numerical models for which data are hard to obtain. © 2015 The Authors. published by John Wiley & Sons Ltd.

摘要

南极洲是世界上最大的淡水库,有可能使海平面上升约60米。当冰盖的冰排放速率和/或表面融化速率超过降雪积累速率时,就会导致海平面上升(SLR)。限制冰盖对当前海平面上升的贡献对于沿海开发与规划以及气候预测都至关重要。关于各种冰盖过程的信息可从多个遥感数据集以及诸如全球定位系统数据等数据中获取。这些数据具有不同的覆盖范围、空间支持、时间采样和传感特性,因此,将它们全部整合在一个单一框架中以估计海平面上升贡献并评估与海洋进行质量交换的控制过程是很有优势的。在本文中,我们预测了南极洲显著地球物理过程导致的高度变化速率,并利用这些来提供海平面上升贡献的估计值以及相关的不确定性。我们采用一个多变量时空模型,近似为高斯马尔可夫随机场,以利用过程不同的时空特性来区分观测到的变化原因。过程参数从地球物理模型中估计,而其余参数使用马尔可夫链蒙特卡罗方案估计,该方案设计用于在跨多个节点的高性能计算环境中运行。我们根据一个单独的数据集验证了我们的方法,并将结果与那些总是直接采用数值模型输出的研究结果进行比较。我们得出结论,在不明确使用数值模型的情况下评估南极洲的贡献是可行且有洞察力的。此外,这里获得的结果可用于测试难以获取数据的地球物理数值模型。© 2015作者。由约翰·威利父子有限公司出版

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本文引用的文献

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Environmetrics. 2014 Jun;25(4):245-264. doi: 10.1002/env.2247. Epub 2013 Dec 26.
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