Evolution of the Mg/Ca ratio of Cretaceous seawater: Implications from the composition of biological low-Mg calcite

Abstract

For the evaluation of variations in the Cretaceous seawater Mg/Ca ratio, 12 shells of rudist bivalves, ranging in age from the Late Barremian (112.2 Ma) to the Early Campanian (81.4 Ma), have been analysed for intra-shell variations in chemical (Mg, Sr, Fe, Mn) and isotopic ( δ 18O, δ 13C) compositions of low-Mg calcite. Preservation of fibrous prismatic ultrastructure, low Fe and Mn concentrations, as well as Sr concentrations within the range of marine biological calcite, indicate only very minor diagenetic alteration. In all studied shells, Mg concentrations and δ 18O-values show a more or less well-defined inverse covariance. This pattern is similar to the conditions observed in modern skeletal calcite, and interpreted to result from a combination of a temperature effect and an unidentified metabolic control on the incorporation of Mg into calcite. Average Mg concentrations in rudist calcite are significantly lower than those of modern bivalves, and increase from the Barremian–Albian to the Campanian, while slopes of δ 18O–Mg regressions are similar to those of modern bivalves. Assuming that the Mg incorporation is linearly dependent on the Mg/Ca ratio of seawater, and that Mg incorporation into calcite of modern bivalve mollusks follows the same metabolic pathway than in their extinct Cretaceous relatives, the Mg/Ca molar ratio of Cretaceous seawater increased from ∼1 in the Late Barremian to ∼3 in the Early Campanian. This trend matches previous model predictions of seawater composition, and experimental results from fluid inclusions in halite. A very low Mg/Ca ratio of seawater is confirmed here to have occurred before the onset of the significant mid-Cretaceous increase of seafloor-production rates in the Late Barremian. Uncertainties in the secular variations of seafloor spreading are discussed, as hydrothermal alteration of young oceanic crust is an important driver of changes in the seawater Mg/Ca ratio.