Abstract
Late Cretaceous sea surface temperatures (SST) are, amongst others, traditionally reconstructed by compiling oxygen isotope records of planktonic foraminifera obtained from globally distributed pelagic IODP drill cores. In contrast, the evolution of Early Cretaceous SSTs is essentially based on the organic TEX86 palaeothermometer, as oxygen-isotope data derived from well-preserved ‘glassy’ foraminifer calcite are currently lacking. In order to evaluate the extraordinary warm TEX86-derived SSTs of the Barremian to Aptian (130–123 Ma) subtropics, we present highly resolved sclerochemical profiles of pristine rudist bivalve shells from Tethyan and proto-North Atlantic shallow water carbonate platforms. An inverse correlation of seasonal ontogenetic variations in δ18Orudist and Mg/Ca ratios demonstrates the fidelity of oxygen isotopes as palaeotemperature proxy. The new data shows moderate mean annual SSTs (22–26 °C) for large parts of the Barremian and Aptian and transient warm pulses for the so-called Mid-Barremian Event and Oceanic Anoxic Event 1a (reaching mean annual SSTs of 28 to 30 °C). A positive shift in mean annual oxygen-isotope values (δ18O: ≤ − 0.3‰) coupled with invariant Mg/Ca ratios at the Barremian–Aptian boundary points to a significant net loss of 16O in Tethyan shallow-marine settings. As the positive oxygen-isotope rudist shell values are recorded immediately beneath a major superregional hiatal surface, they are interpreted to be related to a major cooling phase and potential glacio-eustatic sea-level lowering. Our new sclerochemical findings are in clear contrast to open ocean SST records based on TEX86, which indicate exceptionally warm Barremian to earliest Aptian subtropical oceans and weak meridional SST gradients.
Highlights
Late Cretaceous sea surface temperatures (SST) are, amongst others, traditionally reconstructed by compiling oxygen isotope records of planktonic foraminifera obtained from globally distributed pelagic IODP drill cores
Rudists from the Provence and Jura-Bas-Dauphiné platforms in SE France (Sausset/Cluses: 29°–32° N) provide sclerochronological mean oxygen isotope (δ18Osclero) values ranging between − 3.9 and − 0.3‰
At Kanfanar, rudist shell material ascribed to the onset of OAE1a38 provides a δ18Osclero value of − 2.6‰
Summary
Late Cretaceous sea surface temperatures (SST) are, amongst others, traditionally reconstructed by compiling oxygen isotope records of planktonic foraminifera obtained from globally distributed pelagic IODP drill cores. The study of past greenhouse climates such as the Cretaceous provides fundamental insights into Earth’s response to increased concentrations of greenhouse gases In this context, proxy data-based paleoenvironmental reconstructions play a central role in evaluating the ability of climate models to simulate past, present and future climate change[1]. Reconstructions of Cretaceous open ocean SSTs are predominantly based either on crenarchaeotal membrane lipid distributions (isoGDGTs) from pelagic deposits (referred to as T EX86 proxy) or on oxygen isotope compositions recorded in low-Mg calcite hard parts of planktonic foraminifers[4,6,7,16,17,18,19,20,21,22]. Due to the nektonic lifestyle of these squid-like organisms, belemnite-based SST records are likely influenced by differences in habitat depths ranging from 200 m towards the sea s urface[25]
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