Jurassic constraints on the chaotic Mars-Earth eccentricity cycle linked to the volcanically induced Jenkyns event
成果类型:
Article
署名作者:
Fang, Yanan; Olsen, Paul E.; Sha, Jingeng; Whiteside, Jessica H.; Guan, Chengguo; Ikeda, Masayuki; Li, Sha; Zheng, Daran; Zhang, Haichun; Wang, Bo
署名单位:
Chinese Academy of Sciences; Columbia University; Columbia University; California State University System; San Diego State University; University of Tokyo
刊物名称:
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA
ISSN/ISSBN:
0027-10544
DOI:
10.1073/pnas.2419902122
发表日期:
2025-07-08
关键词:
oceanic anoxic event
early toarcian
carbon-cycle
cheirolepidiaceous conifer
astronomical cycles
junggar basin
bighorn basin
bedded chert
polar wander
time-scale
摘要:
Solar system gravitational interactions are embedded in Earth's record of climate, providing a way to bypass the 60 Myr limit imposed by chaos. Presently with a 2.4 Myr period, the Mars-Earth beat cycle of orbital perihelion frequencies is particularly sensitive to chaotic diffusion, potentially varying by more than a million years. Early Mesozoic (252 to 145 Ma) strata provide some constraints on this cycle, with evidence of a swing through most of the solution space from 1.8 Myr at 210 Ma to 2.5 Myr at 190 Ma and back to 1.6 Myr at 180 Ma. However, only the 1.8 Myr cycle is corroborated by geochronologic data and the 1.6 Myr period is disputed. Here, we show that variations in land-plant-dominated stable carbon isotopic ratios (delta 13Corg) from the lacustrine, paleo-high-latitude Sangonghe Formation (Junggar Basin, northwestern China), reveal at least three 1.6 Myr Mars-Earth beat cycles centered at 183 Ma, tracking atmospheric CO2 isotopic composition in Earth's exchangeable carbon reservoirs. Furthermore, the middle cycle includes the famous Jenkyns Event, expressed here by poleward migration of cheirolepidaceous conifers driven by CO2 warming from the Karoo-Ferrar large igneous province (LIP). Our data do not, however, support major, LIP-triggered input of isotopically light carbon and instead support CO2 amplification of local processes via warming and ecosystem change. Although requiring additional independent geochronological support, Sangonghe data help provide empirical constraints for filtering orbital solutions, tightening initial conditions, and testing gravitational models, as well as showing how extrinsic cyclical processes interact with a tectonic event, the Karoo-Ferrar LIP.