Abstract
Upper Cretaceous marine sequences in the Gulf Coastal Plain (USA) span the Cretaceous–Paleogene (K–Pg) transition, allowing for detailed studies of one of the most severe extinction events of the Phanerozoic. To improve the temporal resolution of the stratigraphic record that represents environmental change leading up to the K–Pg boundary, we constructed a high-resolution chemostratigraphy and cyclostratigraphy of upper Maastrichtian shallow marine deposits located in the state of Mississippi (USA). Upper Maastrichtian strata in this area consist of alternating decimeter scale chalk and marl rhythmites deposited in a hemipelagic setting. New geochemical proxy records were used to test whether rhythmic sedimentation was driven by Milankovitch cycles. Stable isotopes (δ13Ccarb, δ18Ocarb), carbonate content (wt% CaCO3), and elemental concentrations (Ti, K, Fe) integrated with microfossil and ammonite biostratigraphy reveal astronomical forcing in the studied record. Spectral estimation suggests that rhythmic bedding was associated with climate change driven by precession (~20 kyr). Obliquity signals are also apparent in our analysis, and short eccentricity (~100 kyr) is inferred from amplitude modulation of precession. Studied sections were correlated at the precession scale with the recently tuned K–Pg succession near Morello, Italy which is stratigraphically equivalent to the well-characterized K–Pg sites in Gubbio, Italy (Bottaccione, Contessa Highway). Additionally, carbon isotope records from the study area exhibit large scale trends throughout the latest Maastrichtian, similar to those observed in the Morello and Bottaccione sections. Thus, we show that Milankovitch-scale climatic signals and low-amplitude carbon isotope shifts (<0.5‰) of the late Maastrichtian of the Gulf Coastal Plain are well-preserved and can be correlated globally.
| Original language | English |
|---|---|
| Article number | 105954 |
| Journal | Sedimentary Geology |
| Volume | 421 |
| Early online date | 11 Jun 2021 |
| DOIs | |
| Publication status | Published - 15 Jul 2021 |
Bibliographical note
Funding Information:This research was funded by: PSC CUNY (award number 61147-00 49 ), GCAGS (Gulf Coast Association of Geological Societies) and the N.D. Newell Fund (AMNH). We acknowledge Carlsbergfondet CF16-0457 . We are grateful to Stephanie Rodriguez, Kayla Irizarry, Alison Rowe, and Natalie Dastas for assistance in the field, constructive discussions, and editing. Access to the Prairie Bluff Landfill site was provided by Charlie Gardner. Thank you to Colin Carney and Dyke Andreasen (UC Santa Cruz stable isotope laboratory) for conducting the stable isotope analysis. We warmly thank Aura Naujokaitytė, Vilija Naujokaitienė, and Anya Levy for moral support, proofreading assistance, and for assistance with sample preparation in the laboratory.
Funding Information:
This research was funded by: PSC CUNY (award number 61147-00 49), GCAGS (Gulf Coast Association of Geological Societies) and the N.D. Newell Fund (AMNH). We acknowledge Carlsbergfondet CF16-0457. We are grateful to Stephanie Rodriguez, Kayla Irizarry, Alison Rowe, and Natalie Dastas for assistance in the field, constructive discussions, and editing. Access to the Prairie Bluff Landfill site was provided by Charlie Gardner. Thank you to Colin Carney and Dyke Andreasen (UC Santa Cruz stable isotope laboratory) for conducting the stable isotope analysis. We warmly thank Aura Naujokaityt?, Vilija Naujokaitien?, and Anya Levy for moral support, proofreading assistance, and for assistance with sample preparation in the laboratory.
Publisher Copyright:
© 2021 Elsevier B.V.
Keywords
- K–Pg mass extinction
- Cyclostratigraphy
- Stable isotopes
- Orbital cycles
- Chemostratigraphy