A High-Resolution Study of Local Diagenetic Effects on the Geochemistry of the Late Ordovician Kope Formation

dc.contributor.advisorGilhooly, William P., III
dc.contributor.authorBecerra, Evelyn S.
dc.contributor.otherLicht, Kathy
dc.contributor.otherFilippelli, Gabriel
dc.date.accessioned2022-10-04T13:56:50Z
dc.date.available2022-10-04T13:56:50Z
dc.date.issued2022-09
dc.degree.date2022en_US
dc.degree.disciplineDepartment of Earth Scienceen
dc.degree.grantorIndiana Universityen_US
dc.degree.levelM.S.en_US
dc.descriptionIndiana University-Purdue University Indianapolis (IUPUI)en_US
dc.description.abstractThe Ordovician (485-444 Ma) was a highly dynamic period, characterized by significant evolutionary and climatic change. Paleozoic fauna which evolved during the Great Ordovician Biodiversification Event (GOBE) populated extensive epicontinental seaways. Major sea level fluctuations during The Hirnantian glaciation are believed to have led to a mass extinction event at the End Ordovician. However, a reassessment of Early Paleozoic fossil assemblages suggests the onset of extinctions began in the mid-Katian, ~3 million years before the Hirnantian. The Kope formation, within the North American succession of the Katian, was deposited during the peak biodiversification of the GOBE at the point which a biological crisis begins. The well-studied series of interbedded shale and fossiliferous limestone beds, deposited within a shallow epeiric sea, provide ideal sedimentological and paleontological context to interpret sediment geochemistry recorded at the onset of a global mass extinction. For a high-resolution section of the Kope, δ34Spyrite show an extraordinary range of variability, up to 64.5‰, with systematic oscillations throughout the core. The isotope signal represents a mix of pyrite formed at the time of deposition and during diagenesis. As sea levels fluctuated, the amount of sediment delivery influenced the connection of sediment porewaters to overlying seawater sulfate and the location of the sulfate reduction zone, which in turn, masked the primary signal. Reactive iron data suggest low oxygen concentrations in the water column, however fossil assemblages found throughout the Kope suggest otherwise. Changes in sedimentation can mask the water column signal, so these data also capture an aggregate signal. δ15Nbulk show an upsection decrease of 4.4‰, followed by a 3.4‰ increase. Though this excursion can be interpreted as a switch to increased denitrification in a low oxygen environment, the fossil record suggests the data capture localized diagenetic reactions that occur below an oxic water column. Perturbations in the ocean-climate system is often based on the interpretation of stable isotope excursions, and although excursions are diagnostic of changes to biogeochemical cycles, they may not fully account for diagenetic reactions that mask primary signals. The results from the Kope demonstrate strong localized, not global, controls on the sediment geochemistry.en_US
dc.identifier.urihttps://hdl.handle.net/1805/30178
dc.identifier.urihttp://dx.doi.org/10.7912/C2/3034
dc.subjectOrdovicianen_US
dc.subjectKatianen_US
dc.subjectPyrite Sulfur Isotopesen_US
dc.subjectNitrogen Isotopesen_US
dc.subjectPaleoredoxen_US
dc.subjectCyclicityen_US
dc.subjectSea Level Fluctuationsen_US
dc.titleA High-Resolution Study of Local Diagenetic Effects on the Geochemistry of the Late Ordovician Kope Formationen_US
dc.typeThesisen
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