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Mercury isotope evidence for marine photic zone euxinia across the end-Permian mass extinction

Ruoyu Sun, Yi Liu, Jeroen E. Sonke, Feifei Zhang, Yaqiu Zhao, Yonggen Zhang, Jiubin Chen, Cong‐Qiang Liu, Shu‐zhong Shen, Ariel D. Anbar, Wang Zheng

2023Communications Earth & Environment17 citationsDOIOpen Access PDF

Abstract

Abstract The driving forces, kill and recovery mechanisms for the end-Permian mass extinction (EPME), the largest Phanerozoic biological crisis, are under debate. Sedimentary records of mercury enrichment and mercury isotopes have suggested the impact of volcanism on the EPME, yet the causes of mercury enrichment and isotope variations remain controversial. Here, we model mercury isotope variations across the EPME to quantitatively assess the effects of volcanism, terrestrial erosion and photic zone euxinia (PZE, toxic, sulfide-rich conditions). Our numerical model shows that while large-scale volcanism remains the main driver of widespread mercury enrichment, the negative shifts of Δ 199 Hg isotope signature across the EPME cannot be fully explained by volcanism or terrestrial erosion as proposed before, but require additional fractionation by marine mercury photoreduction under enhanced PZE conditions. Thus our model provides further evidence for widespread and prolonged PZE as a key kill mechanism for both the EPME and the impeded recovery afterward.

Topics & Concepts

Photic zoneMercury (programming language)VolcanismExtinction eventGeologyEarth scienceSedimentary rockMass-independent fractionationPermian–Triassic extinction eventIsotopeOceanographyPaleontologyIsotope fractionationChemistryPhytoplanktonTectonicsPhysicsProgramming languageNutrientOrganic chemistryBiological dispersalSociologyComputer scienceQuantum mechanicsDemographyPopulationMercury impact and mitigation studiesPaleontology and Stratigraphy of FossilsIsotope Analysis in Ecology
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