Briner Jason P, Cuzzone Joshua K, Badgeley Jessica A, Young Nicolás E, Steig Eric J, Morlighem Mathieu, Schlegel Nicole-Jeanne, Hakim Gregory J, Schaefer Joerg M, Johnson Jesse V, Lesnek Alia J, Thomas Elizabeth K, Allan Estelle, Bennike Ole, Cluett Allison A, Csatho Beata, de Vernal Anne, Downs Jacob, Larour Eric, Nowicki Sophie
Department of Geology, University at Buffalo, Buffalo, NY, USA.
Department of Earth System Science, University of California Irvine, Irvine, CA, USA.
Nature. 2020 Oct;586(7827):70-74. doi: 10.1038/s41586-020-2742-6. Epub 2020 Sep 30.
The Greenland Ice Sheet (GIS) is losing mass at a high rate. Given the short-term nature of the observational record, it is difficult to assess the historical importance of this mass-loss trend. Unlike records of greenhouse gas concentrations and global temperature, in which observations have been merged with palaeoclimate datasets, there are no comparably long records for rates of GIS mass change. Here we reveal unprecedented mass loss from the GIS this century, by placing contemporary and future rates of GIS mass loss within the context of the natural variability over the past 12,000 years. We force a high-resolution ice-sheet model with an ensemble of climate histories constrained by ice-core data. Our simulation domain covers southwestern Greenland, the mass change of which is dominated by surface mass balance. The results agree favourably with an independent chronology of the history of the GIS margin. The largest pre-industrial rates of mass loss (up to 6,000 billion tonnes per century) occurred in the early Holocene, and were similar to the contemporary (AD 2000-2018) rate of around 6,100 billion tonnes per century. Simulations of future mass loss from southwestern GIS, based on Representative Concentration Pathway (RCP) scenarios corresponding to low (RCP2.6) and high (RCP8.5) greenhouse gas concentration trajectories, predict mass loss of between 8,800 and 35,900 billion tonnes over the twenty-first century. These rates of GIS mass loss exceed the maximum rates over the past 12,000 years. Because rates of mass loss from the southwestern GIS scale linearly with the GIS as a whole, our results indicate, with high confidence, that the rate of mass loss from the GIS will exceed Holocene rates this century.
格陵兰冰盖(GIS)正在以很高的速度流失质量。鉴于观测记录的时间较短,很难评估这种质量流失趋势的历史重要性。与温室气体浓度和全球温度记录不同,后者已将观测数据与古气候数据集合并,而目前尚无关于GIS质量变化速率的可比长时间记录。在这里,我们通过将当代和未来GIS质量流失速率置于过去12000年自然变化的背景下,揭示了本世纪GIS前所未有的质量流失情况。我们使用受冰芯数据约束的一系列气候历史对高分辨率冰盖模型进行了模拟。我们的模拟区域覆盖格陵兰西南部,其质量变化主要由表面质量平衡主导。结果与GIS边缘历史的独立年表高度吻合。工业化前最大的质量流失速率(高达每世纪60000亿吨)发生在全新世早期,与当代(公元2000 - 2018年)约每世纪61000亿吨的速率相似。基于对应低(RCP2.6)和高(RCP8.5)温室气体浓度轨迹的代表性浓度路径(RCP)情景,对格陵兰西南部未来质量流失的模拟预测,在21世纪质量流失将在8800亿至359000亿吨之间。这些GIS质量流失速率超过了过去12000年的最大速率。由于格陵兰西南部的质量流失速率与整个GIS呈线性比例关系,我们的结果高度可靠地表明,本世纪GIS的质量流失速率将超过全新世时期的速率。
