An integrated perspective of paleoenvironmental change in the Western Interior Seaway before and during OAE-2 reveals how organic-rich mudstones form in dynamic environments

•Integrated geochemistry and sedimentology for new paleoenvironmental insights.•Redox and organic matter source change before and during OAE-2 in the Eagle Ford.•Global relationship between organic sulfurization and preservation for OAE-2 sites.•Euxinia allowed organic enrichment to co-occur with se...

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Bibliographic Details
Published inEarth and planetary science letters Vol. 642; p. 118850
Main Authors French, Katherine L., Flaum, Jason A., Birdwell, Justin E.
Format Journal Article
LanguageEnglish
Published Elsevier B.V 15.09.2024
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Summary:•Integrated geochemistry and sedimentology for new paleoenvironmental insights.•Redox and organic matter source change before and during OAE-2 in the Eagle Ford.•Global relationship between organic sulfurization and preservation for OAE-2 sites.•Euxinia allowed organic enrichment to co-occur with sediment transport.•Organic-rich mudstones can form in dynamic environments. Organic and inorganic geochemistry was integrated with sedimentology from the Eagle Ford Group in the U.S. Geological Survey Gulf Coast-3 drill core to investigate why organic matter enrichment and anoxia predate the Cenomanian–Turonian oceanic anoxic event (OAE-2) at the southern Western Interior Seaway (WIS). The relationship between the degree of organic matter sulfurization and preservation in the southern WIS is comparable to OAE-2 sites outside of the WIS, but enhanced organic matter sulfurization and preservation predated OAE-2, distinguishing the southern WIS from other OAE-2 localities. Persistent euxinia and organic matter sulfurization before and during the mid-Cenomanian event (MCE) facilitated maximum organic matter enrichment and preservation to coincide with extensive lateral sediment transport. The new perspective detailed here reconciles geochemical evidence of depositional euxinia with sedimentological evidence of sediment transport, which informs how organic-rich mudstones form in dynamic environments. After the MCE but before OAE-2, reducing conditions weakened as relative sea-level continued to rise, resulting in an oxygen-depleted environment that was prone to transient euxinia. The extent of organic matter sulfurization, preservation, and enrichment declined as euxinia became intermittent. As maximum sea-level was established during OAE-2, boreal water masses flowed into the southern WIS and unrestricted, oxygenated marine conditions developed, which resulted in degradation of marine organic matter and less organic enrichment. The highest relative contribution of marine bacterial organic matter occurred during the persistently euxinic interval before and during the MCE. The relative input of algal organic matter increased as the depositional conditions became less reducing after the MCE but before OAE-2. Prasinophyte green algae contributed to the consistent dominance of C28 steranes preceding OAE-2, which is becoming a widely observed feature across the southern and central WIS. A sharp drop in the C28 sterane relative abundance reflects a decline in the abundance of prasinophytes as oxic depositional conditions developed during OAE-2. Relative abundances of 2-methylhopanes increased during OAE-2, which is a common signature of OAEs, suggesting a modified nitrogen cycle in the offshore southern WIS despite oxic depositional conditions during OAE-2.
ISSN:0012-821X
1385-013X
DOI:10.1016/j.epsl.2024.118850