Calcareous nannofossil biostratigraphy of the Cenomanian/Turonian boundary interval of ODP Leg 207 at the Demerara Rise

During Ocean Drilling Program Leg 207 at Demerara Rise (western tropical Atlantic) expanded sections of organic-rich laminated shales of late Cretaceous age, including the Cenomanian/Turonian boundary interval (CTBI) were recovered. These sediments yield rich assemblages of calcareous nannofossils, offering a unique possibility to calibrate the stable carbon isotope curve (δ¹³C_org). The calcareous nannofossils of Sites 1258, 1259, 1260 and 1261 have been investigated in order to gain a detailed biostratigraphic framework for the CTBI in the tropical latitudes. The bioevents observed have been correlated with the characteristic δ¹³C_org excursion of the CTBI. The events occurring during the excursion, and slightly below and above it, include the first occurrences of the calcareous nannofossil species Cylindralithus biarcus, Quadrum gartneri, Quadrum intermedium, Eprolithus octopetalus, Eprolithus eptapetalus, Eiffellithus eximius and the last occurrences of Corollithion kennedyi and Axopodorhabdus albianus. These bioevents have been correlated with those of other biostratigraphically and chemostratigraphically studied CTBI sections.     

Benthic foraminifera and their role to decipher paleoenvironment during mid-Cretaceous Oceanic Anoxic Events - the “anoxic benthic foraminifera” paradox

Oceanic Anoxic Events (OAEs) are a widespread, recurring and well-studied feature of the mid-Cretaceous greenhouse climate, reflecting severe perturbations in Earth's climate and oceanography. To investigate bottom-water environments before, during and after these OAEs and to understand the dynamic fluctuations of seafloor environments, benthic foraminifera are a commonly employed tool. Here, a review of the response of benthic foraminiferal assemblages to OAEs (i.e., OAEs 1a, 1b, 1d, 2, and 3) will be given. I will discuss in detail how benthic foraminifera can be used to identify the paleoclimatic and paleoceanographic mechanisms responsible for OAE formation. The main feature of benthic foraminiferal assemblages during oceanic anoxic events is a dramatic decrease in both diversities and abundances or their total absence. However, some studies record the permanent occurrence of benthic foraminifera throughout OAEs or short-term repopulation events. These patterns clearly indicate that mid-Cretaceous OAEs are complex events. The paradox of anoxic (and even euxinic) conditions during OAEs coincident with the occurrence of benthic foraminifera (here called the “anoxic benthic foraminifera” paradox) is most readily explained by the sampling (and therefore temporal) resolution of typical foraminiferal studies that have homogenized hundreds to thousands of years in a single sample.     

The Radiolarian biotic response to Oceanic Anoxic Event 2 in the southern part of the Northern proto-Atlantic (Demerara Rise, ODP Leg 207)

Rare Radiolaria occur in the Upper Cenomanian-Lower Turonian part of finely laminated black shales recovered from Sites 1258 and 1261 of Demerara Rise (Ocean Drilling Program Leg 207, western tropical Atlantic, off Surinam). The observed fauna are of a low diversity, with up to 12 species co-occurring in a single sample and 49 species identified in total in both sites. Nassellarians and “Spumellarians” are equally represented in the assemblages. Diverse species of Stichomitra and Theocampe are particularly common, including the two new species described herein: Theocampe costata and T. demeraraense. Radiolarian preservation is on average moderate to poor, suggesting substantial influence of diagenetic alterations to species diversity. The few well-preserved assemblages can potentially provide better information about Cenomanian-Turonian Radiolarian biodiversity, but given their low abundance in the processed sediment samples, the diversity sampled during this study is considered to be an underestimate of the original Radiolarian diversity at Demerara. However, the abundance and diversity of Theocampe in Upper Cenomanian levels is noteworthy. Given the earliest known occurrence of the genus from Upper Albian sediments of the Deep Ivorian Basin it is likely that it originated and diversified in the opening Equatorial Atlantic Gateway. Based on the stable carbon isotope curve, the OAE-2 interval is clearly identified in the sedimentary sequence of both studied sites and helps to specify the known age range of three species (Acanthocircus hueyi, Archaeospongoprunum bipartitum and Rhopalosyringium hispidum). The most intriguing result of this study is the paucity of Radiolaria within the OAE-2 interval of the deeper site (1258) and the total absence of this micro-zooplankton group in the OAE-2 interval of the proximal site (1261). Radiolaria are the most abundant and diverse at the distal Site 1258, below OAE-2, while the proximal Site 1261 contains very few Radiolaria. The opposite pattern is observed above OAE-2 (few Radiolaria at site 1258, more abundant at site 1261). The paucity or absence of Radiolaria within the OAE-2 interval may be due to the upward excursion of the chemocline in the southern part of the Northern proto-Atlantic. Upwelling of deep warm waters may have fuelled primary productivity (sulfate-reducing bacteria) but prevented at the same time micro-zooplankton survival and proliferation after intensification of euxinic conditions in the surface waters.     

Oceanic Anoxic Event at the Cenomanian–Turonian boundary interval (OAE-2): ichnological approach from the Betic Cordillera, southern Spain

Ichnological analysis of dark sediments of the Oceanic Anoxic Event at the Cenomanian–Turonian boundary interval (OAE-2) from the Betic Cordillera, southern Spain, reveals the presence of ichnofabrics containing trace fossils Chondrites isp., Palaeophycus heberti , Planolites isp., Thalassinoides isp., Trichichnus linearis , Zoophycos isp., and other bioturbational structures. Analysis of the ichnofabrics and trace fossil diversity allowed the reconstruction of relative oxygenation. Before the OAE-2, oxygenation of sediments was generally good, but it was punctuated by short anoxic events. During the OAE-2i, several longer anoxic intervals were interrupted by shorter dysaerobic and oxic periods. After the OAE-2, oxygenation improved and almost all trace fossils known before OAE-2 reappeared, although oxygenation dropped a few times to anoxia. Generally, the short oxygenation changes reveal a periodicity, which may suggest a Milankovitch control.