Vertical distribution of benthic foraminifers in the Arctic Ocean

The vertical distribution of living (Rose Bengal stained) benthic foraminifers was determined in the upper 15 cm of sediment cores taken along transects extending from the continental shelf of Spitsbergen through the Eurasian Basin of the Arctic Ocean. Cores taken by a multiple corer were raised from 50 stations with water depths between 94 and 4427 m, from areas with moderate primary production values to areas that are among the least productive ones in the world. We believe, that in the Arctic Ocean the vertical distribution of living foraminifers is determined by the restricted availability of food. Live foraminiferal faunas are dominated by potentially infaunal species or epifaunal species. Species confined to the infaunal microhabitat are absent in Arctic sediments that we examined, and predominantly infaunal living species are nowhere dominant. In general, an infaunal mode of life is restricted to the seasonally ice-free areas and thus to areas with at least moderate primary production during the summer period. Under the permanent ice cover living species are usually restricted to the top centimeter of the sediment surface, even though some are able to dwell deeper in the sediment under ice-free conditions.

Benthic foraminiferal record and age dating of sediment cores from the Gullmar Fjord at the west coast of Sweden

A high-resolution study of benthic foraminiferal assemblages was performed on a ca. eight metre long sediment core from Gullmar Fjord on the west coast of Sweden. The results of 210Pb- and AMS 14C-datings show that the record includes the two warmest climatic episodes of the last 1500 years: the Medieval Warm Period (MWP) and the recent warming of the 20th century. Both periods are known to be anomalously warm and associated with positive NAO winter indices. Benthic foraminiferal successions of both periods are compared in order to find faunal similarities and common denominators corresponding to past climate changes. During the MWP, Adercotryma glomerata, Cassidulina laevigata and Nonionella iridea dominated the assemblages. Judging from dominance of species sensitive to hypoxia and the highest faunal diversity for the last ca. 2400 years, the foraminiferal record of the MWP suggests an absence of severe low oxygen events. At the same time, faunas and d13C values both point to high primary productivity and/or increased input of terrestrial organic carbon into the fjord system during the Medieval Warm Period. Comparison of the MWP and recent warming revealed different trends in the faunal record. The thin-shelled foraminifer N. iridea was characteristic of the MWP, but became absent during the second half of the 20th century. The recent Skagerrak-Kattegat fauna was rare or absent during the MWP but established in Gullmar Fjord at the end of the Little Ice Age or in the early 1900s. Also, there are striking differences in the faunal diversity and absolute abundances of foraminifera between both periods. Changes in primary productivity, higher precipitation resulting in intensified land runoff, different oxygen regimes or even changes in the fjord's trophic status are discussed as possible causes of these faunal differences.

Benthic foraminifera analysed in Skagerrak and Kattegat sediments

a) In der horizontalen Verbreitung sind die vorwiegend kalkschaligen Benthos-Foraminiferen im Untersuchungsgebiet auf zwei Faciesbereiche verteilt: 1. Eine sandige Facies mit stärkeren Temperatur- und Salzgehaltschwankungen; Wasseroberfläche t = 2O-17°C, Salzgehalt nie über 32 per mil, Meerestiefe 30 bis 92 m. 2. Schlick-Facies mit zum Teil feinsandigen Beimengungen. Temperatur- und Salzgehaltschwankungen sind geringer; Wasseroberfläche t = ca. 4O-15° C, Salzgehalt bis 34 per mil, Meerestiefe 135-548 m. b) Einige Stoßröhren-Proben (Station 18, 21, 27, 28) zeigen in ihrer vertikalen Verbreitung auffallende Faunenunterschiede. c) Im Profil des Lotkerns wechseln in der Foraminiferenfauna Bolivinen- und Cassidulinen-Nonioninen-Provinzen miteinander ab. Die Profile der beiden tiefsten Stoßröhren-Kerne (Station 23, 26; s. Tab. I) stimmen in ihrer Mikrofauna mit der des oberen Teils des Lotkerns (s. Tab. 4) überein. d) Die unter b und C angefuührten Faunenwechsel werden auf langperiodische Klimaerwärmungen im skandinavischen Raum und den damit verbundenen Anstieg des Meeresspiegels zurückgeführt. e) Der Lotkern kann mit Hilfe von Untersuchungsergebnissen aus seiner näheren Umgebung (Bohuslän, Oslofjord) nur bedingt in ein stratigraphisches, durch Megafossilien belegtes Schema eingefügt werden, da er nach unten durch die Mikrofauna keine echte Begrenzung aufweist. Durch die Einwanderung mehrerer Foraminiferenarten mit boreal-lusitanischer Verbreitung in die Untersuchungsgebiete wird der Lotkern in die Isocardia-Absätze (Atlanticum-oberes Subboreal) eingegliedert. f) Aus einer Tabelle von PRATJE(1940) kann entnommen werden, daß dieser Zeitabschnitt nach DE GEER etwa um 5000 v.Chr. beginnt. Danach beträgt die geringste Sedimentation, die in dem Kerngebiet nach dieser Zeitrechnung möglich ist, bei einer Eindringtiefe des Lots von 10 m ungefähr 1,40 m pro Jahrtausend. Wahrscheinlich wird dieses Maß etwas größer sein.

Recent benthic foraminifera of the Scotia Sea and Argentine Basin

We investigated 88 surface sediment samples taken with a multiple corer from the southwestern South Atlantic Ocean for their live (Rose Bengal stained) and dead benthic foraminiferal content. Using Q-Mode Principal Component Analysis six live and six dead associations are differentiated. Live and dead association distributions correspond fairly well; differences are mainly caused by downslope transport and selective test destruction. In addition, four potential fossil associations are calculated from the dead data set after removal of non-fossilizable species. These potential fossil associations are expected to be useful for paleoceanographic reconstructions. Environments are described in detail for the live and potential fossil associations and for selected species. Along the upper Argentine continental slope strong bottom currents control the occurrence of live, dead and potential fossil Angulogerina angulosa associations. Here, particles of a high organic carbon flux rate remain suspended. Below this high energy environment live, dead and potential fossil Uvigerina peregrina dominated associations correlate with enhanced sediment organic carbon content and still high organic carbon flux rates. The live A. angulosa and U. peregrina associations correlate with high standing crops. Furthermore, live and dead Epistominella exigua-Nuttallides umbonifer associations were separated. Dominance of a Nuttallides umbonifer potential fossil association relates to coverage by Antarctic Bottom Water (AABW) and Lower Circumpolar Deep Water (LCDW), above the Calcite Compensation Depth (CCD). Three associations of mainly agglutinated foraminifera occur in sediments bathed mainly by AABW or CDW. A Reophax difflugiformis association was found in mud-rich and diatomaceous sediments. Below the CCD, a Psammosphaera fusca association occurs in coarse sediments poor in organic carbon while a Cribrostomoides subglobosus-Ammobaculites agglutinans association covers a more variable environmental range with mud contents exceeding 30%. One single Eggerella bradyi-Martinottiella communis association poor in both species and individuals remains from the agglutinated associations below the CCD if only preservable species are considered for calculation.