Isotope systematics of subfossil, historical, and modern Nautilus macromphalus from New Caledonia
Cephalopod carbonate geochemistry underpins studies ranging from Phanerozoic, global-scale change to outcrop-scale paleoecological reconstructions. Interpreting these data hinges on assumed similarity to model organisms, such as Nautilus , and generalization from other molluscan biomineralization pr...
Published in: | PLOS ONE |
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Main Authors: | , , , , , , |
Other Authors: | , , |
Format: | Article in Journal/Newspaper |
Language: | English |
Published: |
Public Library of Science (PLoS)
2022
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Subjects: | |
Online Access: | http://dx.doi.org/10.1371/journal.pone.0277666 https://dx.plos.org/10.1371/journal.pone.0277666 |
Summary: | Cephalopod carbonate geochemistry underpins studies ranging from Phanerozoic, global-scale change to outcrop-scale paleoecological reconstructions. Interpreting these data hinges on assumed similarity to model organisms, such as Nautilus , and generalization from other molluscan biomineralization processes. Aquarium rearing and capture of wild Nautilus suggest shell carbonate precipitates quickly (35 μm/day) in oxygen isotope equilibrium with seawater. Other components of Nautilus shell chemistry are less well-studied but have potential to serve as proxies for paleobiology and paleoceanography. To calibrate the geochemical response of cephalopod δ 15 N org , δ 13 C org , δ 13 C carb , δ 18 O carb , and δ 44/40 Ca carb to modern anthropogenic environmental change, we analyzed modern, historical, and subfossil Nautilus macromphalus from New Caledonia. Samples span initial human habitation, colonialization, and industrial p CO 2 increase. This sampling strategy is advantageous because it avoids the shock response that can affect geochemical change in aquarium experiments. Given the range of living depths and more complex ecology of Nautilus , however, some anthropogenic signals, such as ocean acidification, may not have propagated to their living depths. Our data suggest some environmental changes are more easily preserved than others given variability in cephalopod average living depth. Calculation of the percent respired carbon incorporated into the shell using δ 13 C org , δ 13 C carb , and Suess-effect corrected δ 13 C DIC suggests an increase in the last 130 years that may have been caused by increasing carbon dioxide concentration or decreasing oxygen concentration at the depths these individuals inhabited. This pattern is consistent with increasing atmospheric CO 2 and/or eutrophication offshore of New Caledonia. We find that δ 44/40 Ca remains stable across the last 130 years. The subfossil shell from a cenote may exhibit early δ 44/40 Ca diagenesis. Questions remain about the proportion of dietary vs ... |
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