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1. Carbonate uranium isotopes record global expansion of marine anoxia during the Toarcian Oceanic Anoxic Event

   https://doi.org/10.1073/pnas.2406032121  

   Remírez, Mariano N; Gilleaudeau, Geoffrey J; Gan, Tian; Kipp, Michael A; Tissot, François_L H; Kaufman, Alan J; Parente, Mariano (July 2024, Proceedings of the National Academy of Sciences)

   The Toarcian Oceanic Anoxic Event (T-OAE; ~183 Mya) was a globally significant carbon-cycle perturbation linked to widespread deposition of organic-rich sediments, massive volcanic CO₂release, marine faunal extinction, sea-level rise, a crisis in carbonate production related to ocean acidification, and elevated seawater temperatures. Despite recognition of the T-OAE as a potential analog for future ocean deoxygenation, current knowledge on the severity of global ocean anoxia is limited largely to studies of the trace element and isotopic composition of black shales, which are commonly affected by local processes. Here, we present the first carbonate-based uranium isotope (δ²³⁸U) record of the T-OAE from open marine platform limestones of the southeastern Tethys Ocean as a proxy for global seawater redox conditions. A significant negative δ²³⁸U excursion (~0.4‰) is recorded just prior to the onset of the negative carbon isotope excursion comprised within the T-OAE, followed by a long-lived recovery of δ²³⁸U values, thus confirming that the T-OAE represents a global expansion of marine anoxia. Using a Bayesian inverse isotopic mass balance model, we estimate that anoxic waters covered ~6 to 8% of the global seafloor during the peak of the T-OAE, which represents 28 to 38 times the extent of anoxia in the modern ocean. These data, combined with δ²³⁸U-based estimates of seafloor anoxic area for other CO₂-driven Phanerozoic OAEs, suggest a common response of ocean anoxia to carbon release, thus improving prediction of future anthropogenically induced ocean deoxygenation. 

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2. Expansion of Reducing Marine Environments During the Ireviken Biogeochemical Event: Evidence From the Altajme Core, Gotland, Sweden

   https://doi.org/10.1029/2022PA004484  

   Stolfus, Brittany M.; Allman, Lindsi J.; Young, Seth A.; Calner, Mikael; Hartke, Emma R.; Oborny, Stephan C.; Bancroft, Alyssa M.; Cramer, Bradley D. (February 2023, Paleoceanography and Paleoclimatology)
3. Lipid biomarkers recording marine microbial community structure changes through the Frasnian‐Famennian mass extinction event

   https://doi.org/10.1111/gbi.12568  

   Chen, Jian; Hogancamp, Nicholas; Lu, Man; Ikejiri, Takehito; Malina, Natalia; Ojeda, Ann; Sun, YongGe; Lu, YueHan (July 2023, Geobiology)

   Abstract Studying the response and recovery of marine microbial communities during mass extinction events provides an evolutionary window through which to understand the adaptation and resilience of the marine ecosystem in the face of significant environmental disturbances. The goal of this study is to reconstruct changes in the marine microbial community structure through the Late Devonian Frasnian‐Famennian (F‐F) transition. We performed a multiproxy investigation on a drill core of the Upper Devonian New Albany Shale from the Illinois Basin (western Kentucky, USA). Aryl isoprenoids show green sulfur bacteria expansion and associated photic zone euxinia (PZE) enhancement during the F‐F interval. These changes can be attributed to augmented terrigenous influxes, as recorded collectively by the long‐chain/short‐chain normal alkane ratio, carbon preference index, C 30 moretane/C 30 hopane, and diahopane index. Hopane/sterane ratios reveal a more pronounced dominance of eukaryotic over prokaryotic production during the mass extinction interval. Sterane distributions indicate that the microalgal community was primarily composed of green algae clades, and their dominance became more pronounced during the F‐F interval and continued to rise in the subsequent periods. The 2α‐methylhopane index values do not show an evident shift during the mass extinction interval, whereas the 3β‐methylhopane index values record a greater abundance of methanotrophic bacteria during the extinction interval, suggesting enhanced methane cycling due to intensified oxygen depletion. Overall, the Illinois Basin during the F‐F extinction experienced heightened algal productivity due to intensified terrigenous influxes, exhibiting similarities to contemporary coastal oceans that are currently undergoing globalized cultural eutrophication. The observed microbial community shifts associated with the F‐F environmental disturbances were largely restricted to the extinction interval, which suggests a relatively stable, resilient marine microbial ecosystem during the Late Devonian. 

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4. Enhanced primary productivity and perturbation of marine nitrogen cycling during the onset of the Cambrian SPICE event

   https://doi.org/10.1016/j.gloplacha.2024.104365  

   Barnes, Gwen L; Cramer, Bradley D (February 2024, Global and Planetary Change)
5. Disease-driven mass mortality event leads to widespread extirpation and variable recovery potential of a marine predator across the eastern Pacific

   https://doi.org/10.1098/rspb.2021.1195  

   Hamilton, S. L.; Saccomanno, V. R.; Heady, W. N.; Gehman, A. L.; Lonhart, S. I.; Beas-Luna, R.; Francis, F. T.; Lee, L.; Rogers-Bennett, L.; Salomon, A. K.; et al (August 2021, Proceedings of the Royal Society B: Biological Sciences)

   null (Ed.)

   The prevalence of disease-driven mass mortality events is increasing, but our understanding of spatial variation in their magnitude, timing and triggers are often poorly resolved. Here, we use a novel range-wide dataset comprised 48 810 surveys to quantify how sea star wasting disease affected Pycnopodia helianthoides , the sunflower sea star, across its range from Baja California, Mexico to the Aleutian Islands, USA. We found that the outbreak occurred more rapidly, killed a greater percentage of the population and left fewer survivors in the southern half of the species's range. Pycnopodia now appears to be functionally extinct (greater than 99.2% declines) from Baja California, Mexico to Cape Flattery, Washington, USA and exhibited severe declines (greater than 87.8%) from the Salish Sea to the Gulf of Alaska. The importance of temperature in predicting Pycnopodia distribution rose more than fourfold after the outbreak, suggesting latitudinal variation in outbreak severity may stem from an interaction between disease severity and warmer waters. We found no evidence of population recovery in the years since the outbreak. Natural recovery in the southern half of the range is unlikely over the short term. Thus, assisted recovery will probably be required to restore the functional role of this predator on ecologically relevant time scales. 

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