Changes in pCO2 and climate paced by grand orbital cycles in the late Cenozoic

IF 4 1区地球科学 Q1 GEOGRAPHY, PHYSICAL

Global and Planetary Change Pub Date : 2024-06-07 DOI:10.1016/j.gloplacha.2024.104493

Yifei Zhang , Qiang Fang , Huaichun Wu , Christian Zeeden , Ying Cui , Meinan Shi , Shihong Zhang , Tianshui Yang , Haiyan Li

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引用次数: 0

Abstract

As one of the most important greenhouse gases, CO₂ is considered a major controlling factor of Earth's climate over geological timescales. However, the origins of quasi-periodic fluctuations in pCO₂ on a million-year timescale remain unclear. Here, we used published datasets of atmospheric pCO₂, oxygen isotopes of benthic foraminifera (δ¹⁸O_benthic) and global mean sea-level (GMSL) from 23 Ma to the present to explore the pacing of pCO₂ changes and concomitant climatic effects using multiple time series analysis approaches. Our results indicate that the evolution of late Cenozoic pCO₂ and climate was paced by the grand orbital cycles, in particular the ~4.5 Myr and ~ 2.4 Myr eccentricity cycles, and ~ 1.3 Myr obliquity cycle. Periodic occurrence of cold conditions was associated with low climate seasonality during the minima of ~4.5 Myr and ~ 2.4 Myr eccentricity cycles. We suggest that cooler conditions are associated with decreased atmospheric pCO₂ as a result of higher organic carbon burial due to lower metabolic rate of heterotrophic bacteria and more organic carbon export to the deep ocean. Furthermore, the buildup of glaciers during the minima of grand eccentricity cycles might lower pCO₂ via increased ice cover and enhanced dust fluxes. In contrast, high seasonal climate may lead to an opposite effect on atmospheric pCO₂ during the maxima of the grand eccentricity cycles. Moreover, we found a distinct shift in the dominant signal from eccentricity to obliquity cycles recorded in the pCO₂, δ¹⁸O_benthic and GMSL datasets at ~13 Ma, a time when perennial sea ice occurred in the Arctic and significant ice growth shown in Antarctica. We suggest that the change in the type and distribution of the ice sheets would shift glacial response to orbital forcing and hence mediated global climate and pCO₂. Our analysis reveals a clear synchrony among atmospheric pCO₂, climate change, and the grand orbital cycles in the late Cenozoic.

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晚新生代以大轨道周期为步调的 pCO2 和气候变化

作为最重要的温室气体之一，二氧化碳被认为是地球气候在地质时间尺度上的主要控制因素。然而，百万年时间尺度上 pCO2 准周期性波动的起源仍不清楚。在此，我们利用大气 pCO2、底栖有孔虫氧同位素（δ18Obenthic）和全球平均海平面（GMSL）从 23 Ma 到现在的已发表数据集，采用多种时间序列分析方法探讨了 pCO2 变化的步调和伴随的气候效应。我们的研究结果表明，晚新生代 pCO2 和气候的演变受大轨道周期的影响，特别是 ~4.5 Myr 和 ~2.4 Myr 偏心率周期以及 ~1.3 Myr 倾角周期。在 ~4.5 Myr 和 ~2.4 Myr 偏心率周期的最小值期间，寒冷条件的周期性出现与低气候季节性有关。我们认为，较冷的条件与大气中 pCO2 的降低有关，这是因为异养细菌的新陈代谢率降低导致有机碳埋藏量增加，以及更多的有机碳输出到深海。此外，在大偏心率周期的最小值期间，冰川的堆积可能会通过增加冰盖和提高尘埃通量来降低 pCO2。相反，在大偏心率周期的最大值期间，高季节性气候可能会对大气中的 pCO2 产生相反的影响。此外，我们发现在约 13 Ma 时，pCO2、δ18 底栖生物和 GMSL 数据集记录到的主要信号从偏心率周期明显转向了斜率周期，而在这一时期，北极出现了常年海冰，南极出现了显著的冰增长。我们认为，冰原类型和分布的变化会改变冰川对轨道强迫的响应，从而影响全球气候和 pCO2。我们的分析揭示了大气 pCO2、气候变化和晚新生代大轨道周期之间明显的同步性。

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来源期刊

Global and Planetary Change 地学天文-地球科学综合

CiteScore

7.40

自引率

10.30%

发文量

226

审稿时长

63 days

期刊介绍： The objective of the journal Global and Planetary Change is to provide a multi-disciplinary overview of the processes taking place in the Earth System and involved in planetary change over time. The journal focuses on records of the past and current state of the earth system, and future scenarios , and their link to global environmental change. Regional or process-oriented studies are welcome if they discuss global implications. Topics include, but are not limited to, changes in the dynamics and composition of the atmosphere, oceans and cryosphere, as well as climate change, sea level variation, observations/modelling of Earth processes from deep to (near-)surface and their coupling, global ecology, biogeography and the resilience/thresholds in ecosystems. Key criteria for the consideration of manuscripts are (a) the relevance for the global scientific community and/or (b) the wider implications for global scale problems, preferably combined with (c) having a significance beyond a single discipline. A clear focus on key processes associated with planetary scale change is strongly encouraged. Manuscripts can be submitted as either research contributions or as a review article. Every effort should be made towards the presentation of research outcomes in an understandable way for a broad readership.