Process-based estimate of global-mean sea-level changes in the Common Era

Earth system dynamics : ESD Pub Date : 2022-10-17 DOI:10.5194/esd-13-1417-2022

Nidheesh Gangadharan, H. Goosse, D. Parkes, H. Goelzer, F. Maussion, B. Marzeion

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引用次数: 2

Abstract

Abstract. Although the global-mean sea level (GMSL) rose over the twentieth century with a positive contribution from thermosteric and barystatic (ice sheets and glaciers) sources, the driving processes of GMSL changes during the pre-industrial Common Era (PCE; 1–1850 CE) are largely unknown. Here, the contributions of glacier and ice sheet mass variations and ocean thermal expansion to GMSL in the Common Era (1–2000 CE) are estimated based on simulations with different physical models. Although the twentieth century global-mean thermosteric sea level (GMTSL) is mainly associated with temperature variations in the upper 700 m (86 % in reconstruction and 74 ± 8 % in model), GMTSL in the PCE is equally controlled by temperature changes below 700 m. The GMTSL does not vary more than ±2 cm during the PCE. GMSL contributions from the Antarctic and Greenland ice sheets tend to cancel each other out during the PCE owing to the differing response of the two ice sheets to atmospheric conditions. The uncertainties of sea-level contribution from land-ice mass variations are large, especially over the first millennium. Despite underestimating the twentieth century model GMSL, there is a general agreement between the model and proxy-based GMSL reconstructions in the CE. Although the uncertainties remain large over the first millennium, model simulations point to glaciers as the dominant source of GMSL changes during the PCE.

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基于过程的共同时代全球平均海平面变化估计

摘要尽管全球平均海平面（GMSL）在20世纪上升，这得益于热物质和重力（冰盖和冰川）来源的积极贡献，但前工业共同时代（PCE；公元前1850年）GMSL变化的驱动过程在很大程度上是未知的。在这里，基于不同物理模型的模拟，估计了共同时代（1–2000 CE）冰川和冰盖质量变化以及海洋热膨胀对GMSL的贡献。尽管20世纪全球平均热海平面（GMTSL）主要与700以上的温度变化有关 m（86 % 重建和74 ± 8. % 在模型中），PCE中的GMTSL同样受到低于700的温度变化的控制 m.GMTSL变化不超过±2 cm。南极和格陵兰冰盖的GMSL贡献在PCE期间往往相互抵消，因为这两个冰盖对大气条件的反应不同。陆地冰块变化对海平面影响的不确定性很大，尤其是在第一个千年。尽管低估了20世纪的GMSL模型，但该模型与CE中基于代理的GMSL重建之间存在着普遍的一致性。尽管第一个千年的不确定性仍然很大，但模型模拟表明，冰川是PCE期间GMSL变化的主要来源。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Earth system dynamics : ESD

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