Abstract
Organic matter production and decomposition primarily modulate the atmospheric O2 and CO2 levels. The long term marine primary productivity is controlled by the terrestrial input of phosphorus (P), while the marine P cycle would also affect organic matter production. In the past 540 million years, the evolution of terrestrial system, e.g. colonization of continents by vascular land plants in late Paleozoic, would certainly affect terrestrial P input into the ocean, which in turn might have impacted the marine primary productivity and organic carbon burial. However, it remains unclear how the marine P cycle would respond to the change of terrestrial system. Here we reconstruct the secular variations of terrestrial P input and biological utilization of seawater P in Phanerozoic. Our study indicates that riverine dissolved P input and marine P biological utilization (i.e. the fraction of P being buried as organophosphorus) are inversely correlated, suggesting the coupling of continental P input and marine P cycle. We propose an increase of P input would elevate surface ocean productivity, which in turn enhances marine iron redox cycle. Active Fe redox cycle favors the scavenging of seawater P through FeOOH absorption and authigenic phosphate formation in sediments, and accordingly reduces the bioavailability of seawater P. The negative feedback of marine P cycle to terrestrial P input would keep a relatively constant organic carbon burial, limiting the variations of surface Earth temperature and atmospheric O2 level.
Highlights
Organic matter production and decomposition primarily modulate the atmospheric O2 and CO2 levels
The biodiversity goes up and down and the animal evolution has been frequently punctuated by mass extinction and the subsequent recovery[1], the Earth System remained habitable for animals in the past 540 million years (Myr)
It is widely accepted that the global temperature is mainly controlled by the pCO2 level in the atmosphere[2], while the surface Earth redox condition is determined by the atmosphere O2 content[3]
Summary
( ) data were collected from chapters in the book: The Geologic Time Scale 201218,19. The iron-bound P from continental input could be remobilized by reduction of ferric Fe, which is associated with organic matter remineralization and releases of ferrous Fe (Fe2+), resulting in the CO2 emission and the reduction of oxidative state of the ocean[14,15,20]. Remobilization of particulate P tends to cancel the effect of organic matter production and have limited impact on the atmospheric pO2 and pCO2 levels. Primary productivity fueled by riverine dissolved P would directly impact the pCO2 and pO2 levels of the atmosphere. Where FSir is the Sr flux of source or sink i, and the subscripts r and hy represent the riverine and hydrothermal inputs, respectively. Because carbonate precipitation is the only major sink of seawater Sr, and Sr in carbonate ( ) ( ) minerals records the seawater Sr isotopic composition, i.e
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