Astronomically controlled deep‐sea life in the Late Cretaceous reconstructed from ultra‐high‐resolution inoceramid shell archives

Adam Wierzbicki (Corresponding author), Erik Wolfgring, Michael Wagreich, Mariusz Kędzierski, Regina Mertz‐Kraus

Publications: Contribution to journalArticlePeer Reviewed

Abstract

The periodicity of the mutual position of celestial bodies in the Earth-Moon-Sun system is crucial to the functioning of life on Earth. Biological rhythms affect most of the processes inside organisms, and some can be recorded in skeletal remains, allowing one to reconstruct the cycles that occur in nature deep in time. In the present study, we have used ultra-high-resolution elemental ratio scans of Mg/Ca, Sr/Ca and Mn/Ca from the fossil, ca. 70 Ma old inoceramid bivalve Inoceramus (Platyceramus) salisburgensis from deep aphotic water and identified a clear regularity of repetition of the geochemical signal every of ~0.006 mm. We estimate that the shell accretion rate is on average ~0.4 cm of shell thickness per lunar year. Visible light–dark lamination, interpreted as a seasonal signal corresponding to the semilunar-related cycle, gives a rough shell age estimate and growth rate for this large bivalve species supported by a dual feeding strategy. We recognize a biological clock that follows either a semilunar (model A) or a tidal (model B) cycle. This cycle of tidal dominance seems to fit better considering the biological behaviour of I. (P.) salisburgensis, including the estimated age and growth rate of the studied specimens. We interpret that the major control in such deep-sea environment, well below the photic zone and storm wave base, was due to barotropic tidal forces, thus changing the water pressure.

Original languageEnglish
Pages (from-to)474-490
Number of pages17
JournalGeobiology
Volume21
Issue number4
Early online date9 Feb 2023
DOIs
Publication statusPublished - Jul 2023

Austrian Fields of Science 2012

  • 105203 Bioclimatology
  • 401101 Cultivation of land
  • 105101 General geology
  • 103006 Chemical physics

Keywords

  • aphotic environment
  • bio-geo-archives
  • biological rhythms
  • bivalves
  • Late Cretaceous
  • ultra-high-resolution data

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