B. A. Black scite author profile

The Siberian Traps fl ood basalts have been invoked as a trigger for the catastrophic end-Permian mass extinction. Widespread aberrant plant remains across the Permian-Triassic boundary provide evidence that atmospheric stress contributed to the collapse in terrestrial diversity. We used detailed estimates of magmatic degassing from the Siberian Traps to complete the fi rst three-dimensional global climate modeling of atmospheric chemistry during eruption of a large igneous province. Our results show that both strongly acidic rain and global ozone collapse are possible transient consequences of episodic pyroclastic volcanism and heating of volatile-rich Siberian country rocks. We suggest that in conjunction with abrupt warming from greenhouse gas emissions, these repeated, rapidly applied atmospheric stresses directly linked Siberian magmatism to end-Permian ecological failure on land. Our comprehensive modeling supplies the fi rst picture of the global distribution and severity of acid rain and ozone depletion, providing testable predictions for the geography of end-Permian environmental proxies.

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Volatiles and the tempo of flood basalt magmatism

Black

Manga

2017

Earth and Planetary Science Letters

100

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Fluvial features on Titan: Insights from morphology and modeling

Burr

Perron

Lamb

et al. 2012

Geological Society of America Bulletin

102

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Systemic swings in end-Permian climate from Siberian Traps carbon and sulfur outgassing

et al. 2018

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Siberian Traps flood basalt magmatism coincided with the end-Permian mass extinction approximately 252 million years ago. Proposed links between magmatism and ecological catastrophe include global warming, global cooling, ozone depletion, and changes in ocean chemistry. However, the critical combinations of environmental changes responsible for global mass extinction are undetermined. In particular, the combined and competing climate effects of sulfur and carbon outgassing remain to be quantified. Here we present results from global climate model simulations of flood basalt outgassing that account for sulfur chemistry and aerosol microphysics with coupled atmosphere and ocean circulation. We consider the effects of sulfur and carbon in isolation and in tandem. We find that coupling with the ocean strongly influences the climate response to flood basaltscale outgassing. We suggest that sulfur and carbon emissions from the Siberian Traps combined to generate systemic swings in temperature, ocean circulation, and hydrology

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Reconciling early Deccan Traps CO ₂ outgassing and pre-KPB global climate

Black

Gibson

Bodnar

et al. 2021

Proc. Natl. Acad. Sci. U.S.A.

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A 2 to 4 °C warming episode, known as the Latest Maastrichtian warming event (LMWE), preceded the Cretaceous–Paleogene boundary (KPB) mass extinction at 66.05 ± 0.08 Ma and has been linked with the onset of voluminous Deccan Traps volcanism. Here, we use direct measurements of melt-inclusion CO2 concentrations and trace-element proxies for CO2 to test the hypothesis that early Deccan magmatism triggered this warming interval. We report CO2 concentrations from NanoSIMS and Raman spectroscopic analyses of melt-inclusion glass and vapor bubbles hosted in magnesian olivines from pre-KPB Deccan primitive basalts. Reconstructed melt-inclusion CO2 concentrations range up to 0.23 to 1.2 wt% CO2 for lavas from the Saurashtra Peninsula and the Thakurvadi Formation in the Western Ghats region. Trace-element proxies for CO2 concentration (Ba and Nb) yield estimates of initial melt concentrations of 0.4 to 1.3 wt% CO2 prior to degassing. Our data imply carbon saturation and degassing of Deccan magmas initiated at high pressures near the Moho or in the lower crust. Furthermore, we find that the earliest Deccan magmas were more CO2 rich, which we hypothesize facilitated more efficient flushing and outgassing from intrusive magmas. Based on carbon cycle modeling and estimates of preserved lava volumes for pre-KPB lavas, we find that volcanic CO2 outgassing alone remains insufficient to account for the magnitude of the observed latest Maastrichtian warming. However, accounting for intrusive outgassing can reconcile early carbon-rich Deccan Traps outgassing with observed changes in climate and atmospheric pCO2.

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Deep Carbon and the Life Cycle of Large Igneous Provinces

Black

Gibson

2019

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Carbon is central to the formation and environmental impact of large igneous provinces (LIPs). These vast magmatic events occur over geologically short timescales and include voluminous flood basalts, along with silicic and low-volume alkaline magmas. Surface outgassing of CO2 from flood basalts may average up to 3,000 Mt per year during LIP emplacement and is subsidized by fractionating magmas deep in the crust. The large quantities of carbon mobilized in LIPs may be sourced from the convecting mantle, lithospheric mantle and crust. The relative significance of each potential carbon source is poorly known and probably varies between LIPs. Because LIPs draw on mantle reservoirs typically untapped during plate boundary magmatism, they are integral to Earth's long-term carbon cycle.

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Morphology of fluvial networks on Titan: Evidence for structural control

Burr

Drummond

Cartwright

et al. 2013

Icarus

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B. A. Black

Magnitude and consequences of volatile release from the Siberian Traps

Acid rain and ozone depletion from pulsed Siberian Traps magmatism

Volatiles and the tempo of flood basalt magmatism

Fluvial features on Titan: Insights from morphology and modeling

Systemic swings in end-Permian climate from Siberian Traps carbon and sulfur outgassing

Reconciling early Deccan Traps CO ₂ outgassing and pre-KPB global climate

Deep Carbon and the Life Cycle of Large Igneous Provinces

Morphology of fluvial networks on Titan: Evidence for structural control

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B. A. Black

Magnitude and consequences of volatile release from the Siberian Traps

Acid rain and ozone depletion from pulsed Siberian Traps magmatism

Volatiles and the tempo of flood basalt magmatism

Fluvial features on Titan: Insights from morphology and modeling

Systemic swings in end-Permian climate from Siberian Traps carbon and sulfur outgassing

Reconciling early Deccan Traps CO 2 outgassing and pre-KPB global climate

Deep Carbon and the Life Cycle of Large Igneous Provinces

Morphology of fluvial networks on Titan: Evidence for structural control

Contact Info

Product

Resources

About

Reconciling early Deccan Traps CO ₂ outgassing and pre-KPB global climate