An independent test of planktic foraminiferal turnover across the Cretaceous/Paleogene (K/P) boundary at El Kef, Tunisia: Catastrophic mass extinction and possible survivorship

Planktic foraminiferal biostratigraphy and assemblage turnover across the C retaceous/Paleogene (WP) boundary at EI Kef revealed the largest and most a brupt extinction event in the history of planktic foraminifera. Cretaceous assemblages were very abundant and diverse and included 67 stable identifie d species within the terminal Maastrichtian. The mass extinction was charac terized by the disappearance of 6 (8.9%) species in the last 12 meters of t he upper Maastrichtian and the extinction of 46 (68.7%) species at the WP b oundary as well as 15 (22.4%) possible survivors ranging into the lowermost Danian. The range of planktic foraminifera only based on six samples (equi valent to the previous El Kef blind sample test) showed an even more catast rophic extinction pattern, with only I species disappearing before the WP b oundary. The WP debate is the result of several problems which include the "Signor-L ipps" effect, the possibility of reworking and the existence of hiatuses. H owever, irrespective of the different interpretations we conclude that ther e were no significant extinction nor quantitative changes before the WP bou ndary and that most Cretaceous species suddenly became extinct at the WP bo undary. The El Kef section is one of the most continuous marine WP boundary sections known and hiatuses have not been identified. Furthermore, possibl e Cretaceous survivors had a smaller size and lower absolute abundance in t he lower Danian than in the upper Maastrichtian and the planktic foraminife ral evolutionary radiation began above the WP boundary and not below. The s ame results have been found in other subtropical-temperate sections and may be sufficient proof for the existence of a catastrophic mass extinction at the WP boundary. The planktic foraminiferal WP extinction pattern is also very compatible with the catastrophic effects caused by the impact of a lar ge extra-terrestrial asteroid.