Phosphate Availability and Implications for Life on Ocean Worlds

Overview

Journal Nat Commun

Specialty Biology

Date 2023 May 15

PMID 37185347

Authors

Noah G Randolph-Flagg

Tucker Ely

Sanjoy M Som

Everett L Shock

Christopher R German

Tori M Hoehler

Affiliations

Soon will be listed here.

Abstract

Several moons in the outer solar system host liquid water oceans. A key next step in assessing the habitability of these ocean worlds is to determine whether life's elemental and energy requirements are also met. Phosphorus is required by all known life and is often limited to biological productivity in Earth's oceans. This raises the possibility that its availability may limit the abundance or productivity of Earth-like life on ocean worlds. To address this potential problem, here we calculate the equilibrium dissolved phosphate concentrations associated with the reaction of water and rocks-a key driver of ocean chemical evolution-across a broad range of compositional inputs and reaction conditions. Equilibrium dissolved phosphate concentrations range from 10 to 10mol/kg across the full range of carbonaceous chondrite compositions and reaction conditions considered, but are generally > 10mol/kg for most plausible scenarios. Relative to the phosphate requirements and uptake kinetics of microorganisms in Earth's oceans, such concentrations would be sufficient to support initially rapid cell growth and construction of global ocean cell populations larger than those observed in Earth's deep oceans.

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