Abstract
Abstract. The protracted recovery of marine ecosystems following the Permian–Triassic mass extinction may have been caused, in part, by episodic environmental and climatic crises during the Early Triassic, among which the Smithian–Spathian boundary (SSB) event is conspicuous. Here, we investigate the SSB event in the Shitouzhai section, Guizhou Province, South China, using a combination of carbonate carbon (δ13Ccarb) and carbonate-associated sulfate sulfur isotopes (δ34SCAS), rare earth elements, and elemental paleoredox and paleoproductivity proxies. The SSB at Shitouzhai is characterized by a +4‰ shift in δ13Ccarb and a −10 to −15‰ shift in δ34SCAS, recording negative covariation that diverges from the positive δ13Ccarb−δ34SCAS covariation that characterizes most of the Early Triassic. This pattern is inferred to reflect an increase in organic carbon burial (e.g., due to elevated marine productivity) concurrently with the oxidation of isotopically light H2S, as the result of enhanced vertical advection of nutrient- and sulfide-rich deep waters to the ocean-surface layer. Enhanced upwelling was likely a response to climatic cooling and the reinvigoration of global-ocean overturning circulation at the SSB. Coeval decreases in chemical weathering intensity and detrital sediment flux at Shitouzhai are also consistent with climatic cooling. A decline in marine biodiversity was probably associated with the late Smithian thermal maximum (LSTM) rather than with the SSB per se. The SSB thus marked the termination of the extreme hothouse conditions of the Griesbachian–Smithian substages of the Early Triassic and is significant as a record of accompanying climatic, environmental, and biotic changes. The ultimate cause of the SSB event is uncertain but may have been related to a reduction in intrusive magmatic activity in the Siberian Traps large igneous province.
Highlights
The recovery of marine invertebrate faunas and ecosystems after the ∼ 252 Ma end-Permian mass extinction appears to have been the most protracted following any Phanerozoic biocrisis (Erwin, 2001; Bottjer et al, 2008)
The extreme environmental conditions (tropical SSTs > 35 ◦C) of the first ∼ 1.5 Myr of the Early Triassic came to an end at the ∼ 250 Ma Smithian– Spathian boundary (SSB), which subdivides the Olenekian stage of the Lower Triassic and which is defined by the first appearance of the conodont Novispathodus pingdingshanen
We correlate this section with existing SSB sections using a combination of conodont biostratigraphic and carbon isotopic constraints, and we examine changes in marine environmental conditions using a combination of elemental and isotopic proxies, with the goal of better understanding the role of the SSB in the recovery of Early Triassic marine ecosystems
Summary
The recovery of marine invertebrate faunas and ecosystems after the ∼ 252 Ma end-Permian mass extinction appears to have been the most protracted following any Phanerozoic biocrisis (Erwin, 2001; Bottjer et al, 2008). The slowness of the recovery process is believed to have resulted, in part, from the effects of sustained or repeated environmental stresses during the Early Triassic (Algeo et al, 2011; Retallack et al, 2011). The extreme environmental conditions (tropical SSTs (sea-surface temperature) > 35 ◦C) of the first ∼ 1.5 Myr of the Early Triassic came to an end at the ∼ 250 Ma Smithian– Spathian boundary (SSB), which subdivides the Olenekian stage of the Lower Triassic and which is defined by the first appearance of the conodont Novispathodus pingdingshanen- The pace of the biotic recovery may have been related to episodic large-scale injection of volcanic CO2 and thermogenic CH4 into the atmosphere, probably from the Siberian Traps large igneous province, and a resulting intensification of ocean anoxia (Retallack and Jahren, 2008; Black et al, 2012).
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