Imprint of relative sea-level histories on last interglacial coral preservation

IF 2.8 3区 地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS
R Cleveland Stout, T Pico, P Huybers, J X Mitrovica, J Austermann
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Abstract

Summary Fossil corals are commonly used to reconstruct Last Interglacial (∼125 ka, LIG) sea level. Sea-level reconstructions assume the water depth at which the coral lived, called the ‘relative water depth’. However, relative water depth varies in time and space due to coral reef growth in response to relative sea-level (RSL) changes. RSL changes can also erode coral reefs, exposing older reef surfaces with different relative water depths. We use a simplified numerical model of coral evolution to investigate how sea-level history systematically influences the preservation of corals in the Bahamas and western Australia, regions which house > 100 LIG coral fossils. We construct global ice histories spanning the uncertainty of LIG global mean sea level (GMSL) and predict RSL with a glacial isostatic adjustment model. We then simulate coral evolution since 132 ka. We show that preserved elevations and relative water depths of modeled LIG corals are sensitive to the magnitude, timing, and number of GMSL highstand(s). In our simulations, the influence of coral growth and erosion (i.e. the ‘growth effect’) can have an impact on RSL reconstructions that is comparable to glacial isostatic adjustment. Thus, without explicitly accounting for the growth effect, additional uncertainty is introduced into sea-level reconstructions. Our results suggest the growth effect is most pronounced in western Australia due to Holocene erosion, but also plays a role in the Bahamas, where LIG RSL rose rapidly due to the collapsing peripheral bulge associated with Laurentide Ice Sheet retreat. Despite the coral model's simplicity, our study highlights the utility of process-based RSL reconstructions.
相对海平面历史对末次冰期珊瑚保存的影响
摘要 珊瑚化石通常用于重建末次冰期(125 ka,LIG)的海平面。海平面重建假定了珊瑚生活的水深,即 "相对水深"。然而,由于珊瑚礁的生长随相对海平面(RSL)的变化而变化,相对水深在时间和空间上也会发生变化。相对海平面的变化也会侵蚀珊瑚礁,暴露出相对水深不同的老珊瑚礁表面。我们使用一个简化的珊瑚演化数值模型来研究海平面历史如何系统地影响巴哈马群岛和澳大利亚西部珊瑚的保存,这些地区保存着 100 个大洋基群珊瑚化石。我们构建了跨越 LIG 全球平均海平面(GMSL)不确定性的全球冰川历史,并利用冰川等静力调整模型预测 RSL。然后,我们模拟了自 132 ka 以来的珊瑚演化过程。我们的研究表明,建模的 LIG 珊瑚保存的海拔高度和相对水深对 GMSL 高点的大小、时间和数量非常敏感。在我们的模拟中,珊瑚生长和侵蚀(即 "生长效应")对 RSL 重建的影响可与冰川等静力调整相媲美。因此,如果不明确考虑生长效应,就会给海平面重建带来额外的不确定性。我们的研究结果表明,由于全新世的侵蚀作用,生长效应在澳大利亚西部最为明显,但在巴哈马群岛也发挥了作用,在那里,由于与劳伦特德冰原退缩相关的外围隆起坍塌,LIG RSL 迅速上升。尽管珊瑚模型很简单,但我们的研究强调了基于过程的 RSL 重建的实用性。
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来源期刊
Geophysical Journal International
Geophysical Journal International 地学-地球化学与地球物理
CiteScore
5.40
自引率
10.70%
发文量
436
审稿时长
3.3 months
期刊介绍: Geophysical Journal International publishes top quality research papers, express letters, invited review papers and book reviews on all aspects of theoretical, computational, applied and observational geophysics.
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