A nitrogen isotopic shift in fish otolith-bound organic matter during the Late Cretaceous
成果类型:
Article
署名作者:
Rao, Zixuan C.; Lueders-Dumont, Jessica A.; Stringer, Gary L.; Ryu, Yeongjun; Zhao, Kewei; Myneni, Satish C.; Oleynik, Sergey; Haug, Gerald H.; Martinez-Garcia, Alfredo; Sigman, Daniel M.
署名单位:
Princeton University; Max Planck Society; Smithsonian Institution; Smithsonian Tropical Research Institute; Boston College; University of Louisiana System; University of Louisiana Monroe; Swiss Federal Institutes of Technology Domain; ETH Zurich
刊物名称:
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA
ISSN/ISSBN:
0027-9751
DOI:
10.1073/pnas.2322863121
发表日期:
2024-08-06
关键词:
trophic position
new-jersey
ocean
nitrate
delta-n-15
temperature
climate
constraints
n-15/n-14
EVOLUTION
摘要:
The nitrogen isotopes of the organic matter preserved in fossil fish otoliths (ear stones) are a promising tool for reconstructing past environmental changes. We analyzed the N-15/N-14 ratio (delta N-15) of fossil otolith-bound organic matter in Late Cretaceous fish otoliths (of Eutawichthys maastrichtiensis, Eutawichthys zideki and Pterothrissus sp.) from three deposits along the US east coast, with two of Campanian (83.6 to 77.9 Ma) and one Maastrichtian (72.1 to 66 Ma) age. delta N-15 and N content were insensitive to cleaning protocol and the preservation state of otolith morphological features, and N content differences among taxa were consistent across deposits, pointing to a fossil-native origin for the organic matter. All three species showed an increase in otolith-bound organic matter delta N-15 of similar to 4 parts per thousand from Campanian to Maastrichtian. As to its cause, the similar change in distinct genera argues against changing trophic level, and modern field data argue against the different locations of the sedimentary deposits. Rather, the lower delta N-15 in the Campanian is best interpreted as an environmental signal at the regional scale or greater, and it may be a consequence of the warmer global climate. A similar decrease has been observed in foraminifera-bound delta N-15 during warm periods of the Cenozoic, reflecting decreased water column denitrification and thus contraction of the ocean's oxygen deficient zones (ODZs) under warm conditions. The same delta N-15-climate correlation in Cretaceous otoliths raises the prospect of an ODZ-to-climate relationship that has been consistent over the last similar to 80 My, applying before and after the end-Cretaceous mass extinction and spanning changes in continental configuration.