A stable oxygen isotope record of weather-timescale variability in the Eocene greenhouse world, using the giant marine gastropod Campanile giganteum

The EGU General Assembly Pub Date : 2021-02-03 DOI:10.5194/EGUSPHERE-EGU21-3268

Nick Van Horebeek, J. Vellekoop, Alexander J. Clark, N. D. de Winter, Yannick Stroobandt, R. Speijer

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引用次数: 1

Abstract

Instrumental climate data are only available for the last few hundred years. To extend this record back in time, climate proxies are used. However, on the geological timescale, the temporal resolution of most paleoclimate records does not provide information about seasonality, let alone events on the weather-timescale. These weather-timescale events are becoming more frequently integrated in models to predict future climate change, but reconstructions of variability with such short timescales in the geological record are extremely rare.

A recent study by de Winter et al. (2020) has revealed that the Eocene giant marine gastropod Campanile giganteum (Lamarck, 1804) had growth rates exceeding 600 mm/year along the helix, far exceeding those of most other modern and fossil molluscs. With such high growth rates, these giant gastropods have the unique potential to record weather-timescale variability in the Eocene greenhouse world. Therefore, we generated a high-resolution (mm-scale) δ¹⁸O record on a well-preserved specimen of C. giganteum from the Paris Basin in Fleury-la-Rivière, France, in order to generate a unique ultra-high resolution record of intra-annual, weather-timescale variability in the Eocene. Our preliminary results show a clear seasonal pattern with δ¹⁸O values ranging between 0.1‰ and -2.5‰, superimposed by weekly variations of up to 0.5‰. This could provide insights in weather patterns in the Eocene greenhouse climate and potentially allow the identification of extreme weather events.

Reference

de Winter N.J., Vellekoop J., Clark A.J., Stassen P., Speijer R.P., Claeys P., (2020) The Giant Marine Gastropod Campanile Giganteum (Lamarck, 1804) as a High‐Resolution Archive of Seasonality in the Eocene Greenhouse World., Geochemistry, Geophysics, Geosystems, 21(4), https://doi.org/10.1029/2019GC008794

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始新世温室世界气候-时间尺度变化的稳定氧同位素记录，使用巨大的海洋腹足动物

仪器气候数据只有最近几百年才有。为了将这一记录追溯到过去，使用了气候代用物。然而，在地质时间尺度上，大多数古气候记录的时间分辨率不能提供有关季节性的信息，更不用说天气时间尺度上的事件了。这些天气时间尺度的事件正越来越频繁地整合到预测未来气候变化的模型中，但在地质记录中以如此短的时间尺度重建变率是极其罕见的。de Winter等人(2020)最近的一项研究表明，始新世巨型海洋腹足动物Campanile giganteum (Lamarck, 1804)沿螺旋的生长速度超过600 mm/年，远远超过大多数其他现代和化石软体动物。由于生长速度如此之快，这些巨型腹足类动物具有独特的潜力，可以记录始新世温室世界的天气-时间尺度变化。因此，我们对来自法国fleury -la- rivi的巴黎盆地的一个保存完好的C. giganteum标本进行了高分辨率(毫米尺度)记录，以便生成始新世年度内天气-时间尺度变化的独特超高分辨率记录。我们的初步结果显示出明显的季节模式，δ18O值在0.1‰和-2.5‰，叠加每周变化0.5‰。这可以提供对始新世温室气候的天气模式的见解，并可能使极端天气事件的识别成为可能[#160;]参考Winter N.J, Vellekoop J.， Clark A.J, Stassen P.， Speijer r.p.， Claeys P.， (2020) the Giant Marine Gastropod Campanile Giganteum (Lamarck, 1804)作为始新世温室世界季节性的高分辨率档案。，地球化学，地球物理，21(4)，https://doi.org/10.1029/2019GC008794

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