Development of carbonate-associated phosphate (CAP) as a proxy for reconstructing ancient ocean phosphate levels

Phosphorus is considered the ultimate limiting nutrient in the oceans over geological timescales. Phosphate (PO43-) availability consequently exerts control on the global carbon cycle and atmospheric/oceanic redox conditions over million-year timescales. Despite its importance, there are no established tools that can directly and continuously reconstruct oceanic phosphate concentrations through time. Here, we report a new approach to carbonate-associated phosphate (CAP) extraction and a series of experiment-based constraints for using CAP as a tool for reconstructing ancient oceanic phosphate concentrations. Experimental work shows that phosphate is incorporated into carbonate at various concentrations as a function of solution phosphate concentration, pH, temperature, and carbonate mineralogy. It is recommended here that in order to selectively extract CAP, carbonate sediments should be partially leached in order to avoid contamination from non-carbonate phases. Analyses of recent and ancient carbonates indicate that CAP values may shift during neomorphic aragonite-to-calcite transformations and secondary alteration. Diagenetic carbonate concretions in the organic-and phosphorus-rich Monterey Formation yield elevated CAP values that correlate with indicators of significant organic matter oxidation; however, this pattern was not observed for geologically young, weakly altered carbonates in the Marion Platform (north-eastern Australian shelf). These observations suggest CAP can yield reliable information on secular variation in oceanic phosphate concentrations and semi-quantitative reconstructions, if samples are characterised mineralogically and screened for secondary alteration. (C) 2021 Elsevier Ltd. All rights reserved.

Automated summary

Phosphorus is crucial in oceanic ecosystems over geological timescales, affecting global carbon cycling and redox conditions. Experimental studies have shown that CAP can be used as a tool for reconstructing ancient oceanic phosphate concentrations, providing valuable insights into the ocean's nutrient history.