Response of Late-Eocene warmth to incipient glaciation on Antarctica

IF 3.8 2区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY
Dennis H.A. Vermeulen, Michiel L. J. Baatsen, Anna S. von der Heydt
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引用次数: 0

Abstract

Abstract. The Eocene-Oligocene Transition (EOT) is marked by a sudden δ18O excursion occurring in two distinct phases, ~500 ky apart. These phases signal a shift from the warm Middle- to Late-Eocene greenhouse climate to cooler conditions, with global surface air temperatures decreasing by 3–5 °C and the emergence of the first continent-wide Antarctic Ice Sheet (AIS). While ice-sheet modelling suggests that ice sheet growth can be triggered by declining pCO2, it still remains unclear how this transition has been initiated, in particular the first growth phase that seems to be related to oceanic and atmospheric cooling rather than ice sheet growth. Recent climate model simulations of the Late-Eocene show improved accuracy but depict climatic conditions that are not conducive to the survival of incipient ice sheets throughout the summer season. This study therefore examines whether it is plausible to develop ice sheets of sufficient scale to trigger the feedback mechanism(s) required to disrupt the atmospheric regime above the Antarctic continent during warm Late-Eocene summers and establish more favourable conditions for ice expansion. We thereby aim to assess the stability of an incipient AIS under varying radiative, orbital and cryospheric forcing. To do so, we evaluate Community Earth System Model 1.0.5 simulations, using a 38 Ma geo- and topographical reconstruction, considering different radiative (4 and 2 pre-industrial carbon) and orbital (present-day and low summer insolation) forcings. The climatic conditions prevailing during (the lead-up to) the EOT can be characterised as extremely seasonal and monsoonal, featuring a short yet intense summer period and contrasting cold winters — highly inhospitable to ice sheet growth for most of the continent, as limited snow accumulation is expected to survive the summer season. A narrow convergence zone with moist convection around the region where sub-cloud equivalent potential temperature is high is shown to exhibit a ring-like structure, advecting moist surface air advected from the Southern Ocean. This advection leads to high values of moist static energy and subsequent precipitation in these regions. To assess the influence of cryospheric forcing, we conducted another simulation, with regional, moderately-sized ice sheets imposed on the continent, to investigate their stability and influence on the atmospheric circulation. Regionally, these relatively small ice sheets respond strongly to radiative and orbital forcing, and demonstrate remarkably favourable self-sustaining and even expansion potential under 2 PIC and low summer insolation conditions. This emphasises a significant hysteresis effect for local and/or regional ice sheets on the Antarctic continent, suggesting the potential for a significant volume of ice on the Antarctic continent without an imminent full glaciation prior to the EOT.
晚始新世温暖对南极洲初期冰川形成的反应
摘要始新世-渐新世过渡(EOT)的标志是δ18O的突然偏移,它分为两个不同的阶段,相距约500 ky。这两个阶段标志着从温暖的中更新世到晚更新世温室气候向凉爽气候的转变,全球地表气温下降了 3-5 °C,并出现了第一块大陆范围的南极冰盖(AIS)。虽然冰盖模拟表明,pCO2 的下降可以触发冰盖的增长,但目前仍不清楚这一转变是如何开始的,特别是第一增长阶段似乎与海洋和大气冷却而非冰盖增长有关。最近的晚始新世气候模型模拟结果表明,模拟的准确性有所提高,但所描述的气候条件不利于初生冰原在整个夏季的生存。因此,本研究探讨了在温暖的晚始新世夏季,是否有可能形成足够规模的冰盖,从而触发所需的反馈机制,扰乱南极大陆上空的大气机制,为冰盖扩张创造更有利的条件。因此,我们的目标是评估在不同的辐射、轨道和冰冻层作用力下,初生的南极冰层信息系统的稳定性。为此,我们评估了共同体地球系统模型 1.0.5 模拟,使用了 38 Ma 的地理和地形重建,考虑了不同的辐射(4 和 2 工业化前碳)和轨道(现今和低夏季日照)强迫。EOT 期间(EOT 前)的气候条件可被描述为季节性极强的季风气候,夏季短暂而强烈,冬季寒冷而对比鲜明--由于夏季积雪有限,因此对大部分大陆的冰盖生长极为不利。在亚云层等效潜在温度较高的区域周围有一个狭窄的湿对流辐合带,呈现环状结构,吸附着从南大洋移入的潮湿表层空气。这种对流导致这些区域的湿静态能量值很高,随后出现降水。为了评估冰冻圈强迫的影响,我们进行了另一次模拟,在大陆上施加了区域性中等大小的冰盖,以研究它们的稳定性和对大气环流的影响。从区域上看,这些相对较小的冰盖对辐射和轨道强迫做出了强烈反应,并在 2 PIC 和夏季低日照条件下表现出明显有利的自我维持甚至扩张潜力。这强调了南极大陆局部和/或区域冰盖的显著滞后效应,表明南极大陆有可能出现大量冰盖,而不会在地球同步轨道之前马上出现全面冰川化。
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来源期刊
Climate of The Past
Climate of The Past 地学-气象与大气科学
CiteScore
7.40
自引率
14.00%
发文量
120
审稿时长
4-8 weeks
期刊介绍: Climate of the Past (CP) is a not-for-profit international scientific journal dedicated to the publication and discussion of research articles, short communications, and review papers on the climate history of the Earth. CP covers all temporal scales of climate change and variability, from geological time through to multidecadal studies of the last century. Studies focusing mainly on present and future climate are not within scope. The main subject areas are the following: reconstructions of past climate based on instrumental and historical data as well as proxy data from marine and terrestrial (including ice) archives; development and validation of new proxies, improvements of the precision and accuracy of proxy data; theoretical and empirical studies of processes in and feedback mechanisms between all climate system components in relation to past climate change on all space scales and timescales; simulation of past climate and model-based interpretation of palaeoclimate data for a better understanding of present and future climate variability and climate change.
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