Sorbonne Université, CNRS, Institut des Sciences de la Terre Paris, ISTeP, F-75005, Paris, France.
ASD/IMCCE, CNRS-UMR8028, Observatoire de Paris, PSL University, Sorbonne Université, 77 Avenue Denfert-Rochereau, 75014, Paris, France.
Sci Rep. 2019 Jan 23;9(1):327. doi: 10.1038/s41598-018-36509-7.
Geological sediment archives document a rich periodic series of astronomically driven climate, but record also abrupt, severe climatic changes called events, the multi-Myr boundary conditions of which have generally been ascribed to acyclic processes from Earth's interior dynamics. These events have rarely been considered together within extended time series for potential correlation with long-term (multi-million year, Myr) cycling. Here I show a coupling between events and multi-Myr cycles in a temperature and ice-volume climatic proxy of the geological past 115 Myr. I use Cenozoic through middle Cretaceous climatic variations, as recorded in benthic foraminifera δO, to highlight prominent 9 and ~36 Myr cyclicities. These cyclicities were previously attributed either to astronomical or tectonic variations. In particular, I point out that most of the well-known events during the past 115 Myr geological interval occur during extremes in the ~9 and ~36 Myr cycling. One exception is the early Cenozoic hyperthermal events including the salient Paleocene-Eocene Thermal Maximum (56 Ma), which do not match extremes in long-period cyclicities, but to inflection point of these cycles. Specific focus on climatic events, as inferred from δO proxy, suggest that some "events", marked by gradual trends within the ~9 and ~36 Myr cycle extremes, would principally be paced by long-term cycling, while "events", recorded as abrupt δO changes nearby cycle extremes, would be rather induced by acyclic processes. The connection between cyclic and acyclic processes, as triggers or feedbacks, is very likely. Such link between cycling and events in Earth's past climate provides insight into celestial dynamics governing perturbations in Earth's surface systems, but also the potential connection between external and Earth's interior processes.
地质沉积档案记录了丰富的天文驱动气候周期性系列,但也记录了称为事件的突然、剧烈的气候变化,这些事件的多百万年边界条件通常归因于地球内部动力学的非周期性过程。这些事件很少在扩展的时间序列中一起考虑,以寻找与长期(数百万年,Myr)循环的潜在相关性。在这里,我展示了过去 115 亿年地质记录中温度和冰量气候代理中事件和多百万年循环之间的耦合。我使用新生代到中白垩世的气候变化,如底栖有孔虫δO 记录,突出显示了明显的9 和36 Myr 周期性。这些周期性以前归因于天文或构造变化。特别是,我指出,在过去 115 亿年地质间隔期间发生的大多数著名事件都发生在9 和36 Myr 循环的极值期间。一个例外是新生代早期的高温事件,包括明显的古新世-始新世极热事件(56 Ma),这些事件与长周期周期性的极值不匹配,但与这些周期的拐点相匹配。从δO 代理推断出的对气候事件的具体关注表明,一些“事件”,在9 和~36 Myr 循环极值内逐渐发展,主要由长期循环控制,而“事件”,在循环极值附近记录为突然的δO 变化,将由非周期性过程引起。周期性和非周期性过程作为触发因素或反馈之间的联系很可能存在。地球过去气候中循环和事件之间的这种联系提供了对天体动力学控制地球表面系统扰动的洞察力,但也提供了外部和地球内部过程之间潜在联系的洞察力。
