The role of ocean circulation and regolith removal in triggering the Mid-Pleistocene Transition: Insights from authigenic Nd isotopes

IF 3.2 1区地球科学 Q1 GEOGRAPHY, PHYSICAL

Quaternary Science Reviews Pub Date : 2024-11-06 DOI:10.1016/j.quascirev.2024.109055

Thomas J. Williams , Alexander M. Piotrowski , Jacob N.W. Howe , Claus-Dieter Hillenbrand , Claire S. Allen , Josephine A. Clegg

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引用次数: 0

Abstract

Approximately 1,250,000 to 700,000 years ago, the pacing of glacial-interglacial cycles changed from 41,000 years to ∼100,000 years, a shift known as the ‘Mid-Pleistocene Transition’ (MPT). The cause – or causes – of this shift remain uncertain. However, changes in ocean circulation and removal of northern hemisphere regolith have both been proposed as potential triggers. Here, we present continuous, orbitally resolved reconstructions of deep ocean neodymium isotopes from three locations in the equatorial Atlantic, Indian and southwest Pacific oceans, spanning 1.7 million years from the Holocene to before the MPT, to test these two hypotheses. We find that global seawater neodymium isotope variability over glacial-interglacial cycles is controlled by changes in both neodymium input to the North Atlantic and deep ocean mixing. Using this neodymium isotope data, we show that enhanced northern hemisphere regolith removal began approximately 1.45 million years ago, ∼200,000 years prior to the onset of the MPT and ∼500,000 years prior to a major expansion in northern hemisphere ice sheets between ∼900,000 and 870,000 years ago. This ice sheet expansion was immediately preceded by an interval of reduced mixing of Atlantic-sourced waters into the deep southwest Pacific Ocean. We hypothesize that this circulation reorganization reflected increased stratification of the deep Southern Ocean interior, possibly in response to cooling and Antarctic sea ice expansion at this time. Taken together, these data suggest an expansion and/or thickening of northern hemisphere ice sheets during the MPT was facilitated by a combination of reduced northern hemisphere regolith cover alongside Southern Ocean circulation changes. Together, these shifts allowed the build up of larger northern hemisphere ice sheets that were more resistant to deglaciation, facilitating the longer glacial cycles of the post-MPT world.

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海洋环流和碎屑岩移除在引发中更新世过渡中的作用：自生钕同位素的启示

大约 125 万年至 70 万年前，冰川-间冰期周期的步调从 4.1 万年变为 10 万年，这一转变被称为 "中更新世过渡"（MPT）。这一转变的原因仍不确定。然而，海洋环流的变化和北半球碎屑岩的移除都被认为是潜在的触发因素。在这里，我们展示了赤道大西洋、印度洋和西南太平洋三个地点的深海钕同位素的连续、轨道解析重建结果，时间跨度为全新世至 MPT 之前的 170 万年，以检验这两种假设。我们发现，冰川-间冰期周期的全球海水钕同位素变化受北大西洋钕输入和深海混合的变化控制。利用这些钕同位素数据，我们表明北半球碎屑岩移除的增强大约始于 145 万年前，比大冰期开始早 20 万年，比北半球冰盖在 90 万年至 87 万年前的一次大扩张早 50 万年。在冰盖扩张之前，来自大西洋的海水进入西南太平洋深层的混合活动曾一度减少。我们假设，这种环流重组反映了南大洋内部深层分层的增加，可能是对此时南极海冰扩张和降温的反应。综合来看，这些数据表明，北半球碎屑岩覆盖面积的减少和南大洋环流的变化共同促进了北半球冰盖在大洋深度年期间的扩张和/或增厚。这些变化使得北半球冰盖的面积增大，更能抵御冰川消融，从而促进了后大冰期世界更长的冰川周期。

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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来源期刊

Quaternary Science Reviews 地学-地球科学综合

CiteScore

7.50

自引率

15.00%

发文量

388

审稿时长

3 months

期刊介绍： Quaternary Science Reviews caters for all aspects of Quaternary science, and includes, for example, geology, geomorphology, geography, archaeology, soil science, palaeobotany, palaeontology, palaeoclimatology and the full range of applicable dating methods. The dividing line between what constitutes the review paper and one which contains new original data is not easy to establish, so QSR also publishes papers with new data especially if these perform a review function. All the Quaternary sciences are changing rapidly and subject to re-evaluation as the pace of discovery quickens; thus the diverse but comprehensive role of Quaternary Science Reviews keeps readers abreast of the wider issues relating to new developments in the field.