古新世和始新世碳循环的轨道强迫

R. Zeebe, T. Westerhold, K. Littler, J. Zachos
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引用次数: 48

摘要

古新世和始新世的数百万年代理记录显示,轨道时间尺度存在显著变化。这些周期已在全球各地被发现,优先将光谱功率集中在离心率和岁差频率。很明显,这些周期是全球气候变化和天文强迫下的碳循环的表现。然而,目前对轨道强迫与碳循环气候系统以及相关大气二氧化碳变化幅度之间的联系知之甚少。在这里,我们使用简单和复杂的碳循环模型来探索不同轨道强迫方案和噪声对碳循环的基本影响。我们的主要建模目标是南大西洋海洋钻探项目1262号场地的高分辨率、约7.7 Myr长的海底同位素记录。对于直接日射强迫(与人工偏心倾斜进动相反),一个主要挑战是了解系统如何将频谱功率从高频转移到低频。我们讨论了可行的解决方案,包括类似于电子AC-DC转换(DC’ing)的日射变换。关于机制,我们关注热带日照和陆地有机物埋藏/氧化中的长期碳失衡,但不排除其他情况。我们的分析表明,高纬度机制不太可能是古新世晚期-始新世早期(LPEE)地球系统轨道速度变化的驱动因素。此外,我们对可能的LPEE循环碳不平衡/源的起源和同位素组成进行了限制,以应对天文强迫。我们的模拟还揭示了在古新世、渐新世和中新世剖面中观察到的400 kyr时期的大δ13C离心率滞后的机制。我们首次估计了古新世晚期和始新世早期大气CO2的轨道尺度变化。
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Orbital forcing of the Paleocene and Eocene carbon cycle
Multimillion-year proxy records across the Paleocene and Eocene show prominent variations on orbital time scales. The cycles, which have been identified at various sites across the globe, preferentially concentrate spectral power at eccentricity and precessional frequencies. It is evident that these cycles are an expression of changes in global climate and carbon cycling paced by astronomical forcing. However, little is currently known about the link between orbital forcing and the carbon cycle-climate system and the amplitude of associated atmospheric CO2 variations. Here we use simple and complex carbon cycle models to explore the basic effect of different orbital forcing schemes and noise on the carbon cycle. Our primary modeling target is the high-resolution, ∼7.7 Myr long, benthic isotope record at Ocean Drilling Program Site 1262 in the South Atlantic. For direct insolation forcing (as opposed to artificial eccentricity-tilt-precession), one major challenge is understanding how the system transfers spectral power from high to low frequencies. We discuss feasible solutions, including insolation transformations analogous to electronic AC-DC conversion (DC'ing). Regarding mechanisms, we focus on tropical insolation and a long-term carbon imbalance in terrestrial organic burial/oxidation but do not rule out other scenarios. Our analysis shows that high-latitude mechanisms are unlikely drivers of orbitally paced changes in the late Paleocene-early Eocene (LPEE) Earth system. Furthermore, we provide constraints on the origin and isotopic composition of a possible LPEE cyclic carbon imbalance/source responding to astronomical forcing. Our simulations also reveal a mechanism for the large δ13C-eccentricity lag at the 400 kyr period observed in Paleocene, Oligocene, and Miocene sections. We present the first estimates of orbital-scale variations in atmospheric CO2 during the late Paleocene and early Eocene.
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Paleoceanography
Paleoceanography 地学-地球科学综合
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