Triple oxygen isotope systematics of diagenetic recrystallization of diatom opal-A to opal-CT to microquartz in deep sea sediments

The oxygen-18 isotopic composition (delta O-18) of silica preserved in oceanic sediments is an important archive of Earth's temperature and/or seawater delta O-18 from the Archean to present. Recent advances in high-precision measurements of both delta O-18 and delta O-17 values have been used to provide additional constraints on what the oxygen isotopic composition of chert reflects about past conditions. Here, we examine the effects on the triple oxygen isotopic composition of chert that occurs during transformation and recrystallization of biogenic opal-A to opal-CT to microquartz in deep sea sediments. We studied late Miocene to present samples from the Sea of Japan at ODP Site 795 and measured biogenic diatom opal-A, opal-CT, micro quartz chert, and 'altered' opal-A samples-previously measured for delta O-18 values only-for both delta O-18 and delta O-17 values. We find that delta O-18 decreases and & UDelta;0(17)O increases (where & UDelta;0(17)O = delta O-17 - 0.528 x delta O-18) with depth, coincident with the conversions from diatom opal-A to opal-CT to microquartz. Silica samples deviate from the trend expected for triple oxygen isotopic equilibrium with modern seawater. To explain these data, we developed a model that shows that local temperature gradients and pore fluid delta O-18 profiles in combination lower the measured opal-CT and microquartz delta O-18 values and raise the & UDelta;0(17)O values relative to the initial opal-A, but deviate from triple oxygen isotopic equilibrium with seawater. We find that a steeper local temperature gradient and a larger influence of hydrothermal alteration of basalt at the base of the sediment column (which lowers pore fluid delta O-18 values) in the past explain both the measured delta O-18 and & UDelta;0(17)O values of the opal-CT and microquartz. These data and our modeling show that the transformation of opal-A to microquartz in marine sediments at elevated temperatures and in the presence of lowered pore water delta O-18 values leads to an array that falls below the theoretical triple oxygen isotope line of equilibrium for SiO2 with modern seawater. Further, our model indicates that opal-CT and microquartz do form in triple oxygen isotopic equilibrium with pore fluids that are offset in their triple oxygen isotopic composition compared to seawater due to fluid-rock alteration of igneous rocks at the base of the sediment column. The diagenetic processes taking place in the Japan Sea do not explain a large portion of the existing Archean to present triple oxygen isotope chert data, which likely require either changes in the oxygen isotopic composition of the source water (i.e., ocean water) and/or alteration by meteoric fluids. Further, our data demonstrate that the triple oxygen isotopic composition of preserved chert need not represent surface conditions, but instead may reflect processes that occur in subsurface sediments at elevated temperatures and with modified pore fluid oxygen isotopic compositions.(c) 2021 Elsevier Ltd. All rights reserved.

Automated summary

The oxygen isotopic composition of silica preserved in oceanic sediments has been studied in this research. The results show that the transformation and recrystallization processes of biogenic opal-A to opal-CT to microquartz in deep sea sediments have significant effects on the triple oxygen isotopic composition of chert. The findings suggest that the local temperature gradients and pore fluid oxygen isotopic compositions influence the measured values of chert, deviating from triple oxygen isotopic equilibrium with seawater.