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Permo–Triassic boundary carbon and mercury cycling linked to terrestrial ecosystem collapse

Jacopo Dal Corso, Benjamin Mills, Daoliang Chu, Robert J. Newton, Tamsin A. Mather, Wenchao Shu, Yuyang Wu, Jinnan Tong, Paul B. Wignall

2020Nature Communications81 citationsDOIOpen Access PDF

Abstract

Abstract Records suggest that the Permo–Triassic mass extinction (PTME) involved one of the most severe terrestrial ecosystem collapses of the Phanerozoic. However, it has proved difficult to constrain the extent of the primary productivity loss on land, hindering our understanding of the effects on global biogeochemistry. We build a new biogeochemical model that couples the global Hg and C cycles to evaluate the distinct terrestrial contribution to atmosphere–ocean biogeochemistry separated from coeval volcanic fluxes. We show that the large short-lived Hg spike, and nadirs in δ 202 Hg and δ 13 C values at the marine PTME are best explained by a sudden, massive pulse of terrestrial biomass oxidation, while volcanism remains an adequate explanation for the longer-term geochemical changes. Our modelling shows that a massive collapse of terrestrial ecosystems linked to volcanism-driven environmental change triggered significant biogeochemical changes, and cascaded organic matter, nutrients, Hg and other organically-bound species into the marine system.

Topics & Concepts

Biogeochemical cycleBiogeochemistryExtinction eventVolcanismTerrestrial ecosystemEcosystemEarth scienceCarbon cycleMarine ecosystemVolcanoPhanerozoicGeologyOceanographyGeologic recordEnvironmental scienceEcologyPaleontologyBiologyCenozoicStructural basinTectonicsBiological dispersalDemographySociologyPopulationPaleontology and Stratigraphy of FossilsGeochemistry and Elemental AnalysisMercury impact and mitigation studies
Permo–Triassic boundary carbon and mercury cycling linked to terrestrial ecosystem collapse | Litcius