TY - JOUR
T1 - Jurassic shift from abiotic to biotic control on marine ecological success
AU - Eichenseer, Kilian
AU - Balthasar, Uwe
AU - Smart, Christopher W.
AU - Stander, Julian
AU - Haaga, Kristian A.
AU - Kiessling, Wolfgang
PY - 2019/7/1
Y1 - 2019/7/1
N2 - Environmental change and biotic interactions both govern the evolution of the biosphere, but the relative importance of these
drivers over geological time remains largely unknown. Previous work suggests that, unlike environmental parameters, diversity
dynamics differ profoundly between the Palaeozoic and post-Palaeozoic eras. Here we use the fossil record to test the hypothesis
that the influence of ocean chemistry and climate on the ecological success of marine calcifiers decreased throughout the
Phanerozoic eon. Marine calcifiers build skeletons of calcite or aragonite, and the precipitation of these calcium carbonate
polymorphs is governed by the magnesium-to-calcium ratio and temperature in abiotic systems. We developed an environmental
forcing model based on secular changes of ocean chemistry and temperature and assessed how well the model predicts the
proliferation of skeletal taxa with respect to calcium carbonate polymorphs. Abiotic forcing governs the ecological success of
aragonitic calcifiers from the Ordovician to the Middle Jurassic, but not thereafter. This regime shift coincides with the proliferation
of calcareous plankton in the mid-Mesozoic. The deposition of biomineralizing plankton on the ocean floor buffers CO2
excursions and stabilizes Earth’s biochemical cycle, and thus mitigates the evolutionary impact of environmental change on the
marine biota.
AB - Environmental change and biotic interactions both govern the evolution of the biosphere, but the relative importance of these
drivers over geological time remains largely unknown. Previous work suggests that, unlike environmental parameters, diversity
dynamics differ profoundly between the Palaeozoic and post-Palaeozoic eras. Here we use the fossil record to test the hypothesis
that the influence of ocean chemistry and climate on the ecological success of marine calcifiers decreased throughout the
Phanerozoic eon. Marine calcifiers build skeletons of calcite or aragonite, and the precipitation of these calcium carbonate
polymorphs is governed by the magnesium-to-calcium ratio and temperature in abiotic systems. We developed an environmental
forcing model based on secular changes of ocean chemistry and temperature and assessed how well the model predicts the
proliferation of skeletal taxa with respect to calcium carbonate polymorphs. Abiotic forcing governs the ecological success of
aragonitic calcifiers from the Ordovician to the Middle Jurassic, but not thereafter. This regime shift coincides with the proliferation
of calcareous plankton in the mid-Mesozoic. The deposition of biomineralizing plankton on the ocean floor buffers CO2
excursions and stabilizes Earth’s biochemical cycle, and thus mitigates the evolutionary impact of environmental change on the
marine biota.
UR - https://pearl.plymouth.ac.uk/context/gees-research/article/1148/viewcontent/Eichenseer_et_al_Nature_Geoscience_2019.pdf
U2 - 10.1038/s41561-019-0392-9
DO - 10.1038/s41561-019-0392-9
M3 - Article
SN - 1752-0894
VL - 0
JO - Nature Geoscience
JF - Nature Geoscience
IS - 0
ER -