6533b826fe1ef96bd1284915
RESEARCH PRODUCT
Early Paleocene Paleoceanography and Export Productivity in the Chicxulub Crater
Lowery C.m.Jones H.l.Bralower T.j.Cruz L.p.Gebhardt C.Whalen M.t.Chenot E.Smit J.Phillips M.p.Choumiline K.Arenillas I.Arz J.a.Garcia F.Ferrand M.Gulick S.p.s.Christeson G.Claeys P.Cockell C.Coolen M.Ferrière L.Goto K.Green S.Grice K.Kring D.Lofi J.Mellett C.Morgan J.Ocampo-torres R.Pickersgill A.Poelchau M.Rae A.Rasmussen C.Rebolledo-vieyra M.Riller U.Sato H.Schaefer B.Tikoo S.Tomioka N.Urrutia-fucugauchi J.Wittmann A.Xiao L.Yamaguchi K.Zylberman W.Expedition 364 Science Partysubject
bepress|Physical Sciences and Mathematics|Earth Sciences|Paleontologybepress|Physical Sciences and Mathematicsbepress|Physical Sciences and Mathematics|Earth Sciences|Sedimentology010506 paleontologyAtmospheric Science010504 meteorology & atmospheric sciencesbepress|Physical Sciences and Mathematics|Earth SciencesEarthArXiv|Physical Sciences and Mathematics|Earth Sciences010502 geochemistry & geophysicsOceanography01 natural sciencesForaminifera/dk/atira/pure/sustainabledevelopmentgoals/life_below_waterWater columnImpact craterPaleoceanographyPhytoplanktonPhotic zone14. Life underwaterSDG 14 - Life Below WaterEarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Sedimentology0105 earth and related environmental sciencesbiologyTerrigenous sedimentPaleontologyEarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Geochemistry15. Life on landEarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Paleontologybiology.organism_classificationhumanitiesEarthArXiv|Physical Sciences and MathematicsOceanographyProductivity (ecology)13. Climate action[SDU.STU.ST]Sciences of the Universe [physics]/Earth Sciences/StratigraphyEnvironmental sciencebepress|Physical Sciences and Mathematics|Earth Sciences|Geochemistrydescription
The Chicxulub impact caused a crash in productivity in the world''s oceans which contributed to the extinction of ~75% of marine species. In the immediate aftermath of the extinction, export productivity was locally highly variable, with some sites, including the Chicxulub crater, recording elevated export production. The long-term transition back to more stable export productivity regimes has been poorly documented. Here, we present elemental abundances, foraminifer and calcareous nannoplankton assemblage counts, total organic carbon, and bulk carbonate carbon isotope data from the Chicxulub crater to reconstruct changes in export productivity during the first 3 Myr of the Paleocene. We show that export production was elevated for the first 320 kyr of the Paleocene, declined from 320 kyr to 1.2 Myr, and then remained low thereafter. A key interval in this long decline occurred 900 kyr to 1.2 Myr post impact, as calcareous nannoplankton assemblages began to diversify. This interval is associated with fluctuations in water column stratification and terrigenous flux, but these variables are uncorrelated to export productivity. Instead, we postulate that the turnover in the phytoplankton community from a post-extinction assemblage dominated by picoplankton (which promoted nutrient recycling in the euphotic zone) to a Paleocene pelagic community dominated by relatively larger primary producers like calcareous nannoplankton (which more efficiently removed nutrients from surface waters, leading to oligotrophy) is responsible for the decline in export production in the southern Gulf of Mexico. © 2021. American Geophysical Union. All Rights Reserved.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2021-11-01 |