# A sluggish mid-Proterozoic biosphere and its effect on Earth's redox   balance

**Authors:** Kazumi Ozaki, Christopher T. Reinhard, Eiichi Tajika

arXiv: 1907.13567 · 2019-08-01

## TL;DR

This study models the mid-Proterozoic Earth's biogeochemical cycles to understand how low but stable oxygen levels were maintained, highlighting phosphorus scarcity and sulfur cycle's role in Earth's redox balance.

## Contribution

It introduces a comprehensive biogeochemical model constrained by geological data to quantify oxygen production and regulation mechanisms during the mid-Proterozoic.

## Key findings

- Net biospheric O2 production was about 25% of today's levels.
- Phosphorus scarcity limited biological productivity and oxygen levels.
- Sulfur cycle processes significantly contributed to redox balance.

## Abstract

The possibility of low but nontrivial atmospheric oxygen (O2) levels during the mid-Proterozoic (between 1.8 and 0.8 billion years ago, Ga) has important ramifications for understanding Earth's O2 cycle, the evolution of complex life and evolving climate stability. However, the regulatory mechanisms and redox fluxes required to stabilize these O2 levels in the face of continued biological oxygen production remain uncertain. Here, we develop a biogeochemical model of the C-N-P-O2-S cycles and use it to constrain global redox balance in the mid-Proterozoic ocean-atmosphere system. By employing a Monte Carlo approach bounded by observations from the geologic record, we infer that the rate of net biospheric O2 production was 3.5 (+1.4 - 1.1) Tmol year-1 (1-sigma), or ~25% of today's value, owing largely to phosphorus scarcity in the ocean interior. Pyrite burial in marine sediments would have represented a comparable or more significant O2 source than organic carbon burial, implying a potentially important role for Earth's sulphur cycle in balancing the oxygen cycle and regulating atmospheric O2 levels. Our statistical approach provides a uniquely comprehensive view of Earth system biogeochemistry and global O2 cycling during mid-Proterozoic time and implicates severe P biolimitation as the backdrop for Precambrian geochemical and biological evolution.

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Source: https://tomesphere.com/paper/1907.13567