Calcareous plankton biostratigraphic fidelity and species richness during the last 10 m.y. of the Cretaceous at Blake Plateau, subtropical North Atlantic

Species distributions of well-preserved and diverse assemblages of planktonic foraminifera and calcareous nannofossils spanning the last 10 m.y. of the Cretaceous (middle Campanian through Maastrichtian) are analyzed from samples taken across a 1400 m depth transect at Blake Nose in the western subtropical North Atlantic (Ocean Drilling Program Sites 1049, 1050 and 1052). Age models constructed by integrating fora-miniferal, calcareous nannofossil, and magnetic polarity datum events provide a reliable framework for temporal correlation of the sites. This framework enables comparisons of species richness and abundance among sites and evaluation of the reliability of first and last appearance datums for regional and global correlation. Among the standard primary zonal marker datums, six of nine planktonic foraminifer and six of seven calcareous nannofossil events are considered reliable for constraining the age-depth models. Sec-ondary datum ages calculated for 17 planktonic foraminiferal events suggest correlation offsets among the three sites of <0.1 m.y. for four species (including Pseudoguembelina praehariaensis Tur and Huber n. sp.), 0.1-0.5 m.y. for six events, and 0.6-1.0 m.y. for eight species. Secondary calcareous nannofossil datum ages calculated for six species show less reliability, with offsets of <0.1 m.y. for one species, 0.7 m.y. for one species, and 1.0-1.5 m.y. for the remaining four species. The distinctly identifiable new species Trinitella suturis Tur and Huber has lowest occurrences that are diachronous by as much as 1.73 m.y. among the Blake Nose sites. Occurrence rarity is the most likely explanation for the age offsets of this and other diachronous species. Planktonic foraminiferal assemblages show no significant differences in species composition and relative abundance among the three sites, suggesting the sites were all located below a single oligo-trophic surface water mass. Species richness counts pooled in 200 kyr bins for the Blake Nose sites re-veals high species origination rates from the late Campanian through early Maastrichtian and highest species richness (51-63 species) during the Maastrichtian. The only significant extinction pulse during the mid-Campanian through Maastrichtian occurs between 66.2 and 66.4 Ma with loss of five species representing-9% of the assemblage. These extinctions occur at the same time as a globally recognized warming event correlated with a pulse of eruptions at the Deccan Traps in India. Calcareous nannofossil assemblages show no significant change in relative abundance among the three sites. Two significantextinction eventsaredocumented: one from 75.20 to 75.40 Mawith a loss of six speciesrepresenting-6% of the assemblage and one from 66.2 to 66.4 Ma with a loss of nine species representing-9% of the assemblage. The former event is associated with a hiatus at the base of Zone CC24, and the latter corresponds to Deccan Trap warming. Hiatuses are identified at all three Blake Nose sites near the base of the Maastrichtian (-71.5 Ma; lowermost Pseudoguembelina palpebra/CC24 Zone) and only at the deeper Sites 1049 and 1050 in the mid-Maastrichtian (-67.2 Ma; Pseudoguembelina hariaensis/CC26b Zone) and the mid-Campanian (-75.9 Ma; base of Radotruncana calcarata/CC22 Zone). Slumping from across the shelf and slope could have caused the early Maastrichtian hiatus while changes in the pattern and strength of deep-water circulation may have been responsible for the mid-Maastrichtian and mid-Campanian hiatuses. Published by Elsevier Ltd.

Automated summary

The study analyzed the distribution of well-preserved and diverse planktonic foraminifera and calcareous nannofossils over the past 10 million years in the western subtropical North Atlantic. Through age models constructed based on foram, nannofossil, and magnetic polarity datum events, reliable temporal correlation framework was established for the sites, enabling comparisons of species richness and abundance among sites. The study also revealed significant extinction events and hiatuses at specific time intervals linked to global warming events and changes in deep-water circulation patterns.