Während der Tiefsee-Expedition SO 158 mit F.S 'Sonne' in das Gebiet zwischen Galapagosspreizungszentrum und -plattform sollen bodenlebende Meeresorganismen gesammelt werden. Die Auswertung wird sich auf die Schlüsselgruppen Kinorhyncha, Loricifera, Copepoda, Brachiopoda und Porifera konzentrieren, die nach den Erfahrungen bei früheren Tiefsee-Expeditionen in genügend hoher Anzahl im Weichboden und auf Steinen zu erwarten sind. Die großräumige Variabilität von Tiefsee-Tiergemeinschaften im Ostpazifik soll untersucht werden, um Aussagen über das Verbreitungsareal von Tierarten in der Tiefsee und über den Einfluß von geomorphologischen Strukturen wie dem Spreizungszentrum treffen zu können. Außerdem sollen potentielle Anpassungen (Sinnesorgane, endosymbiontische Bakterien in Darm oder Integument?) an das Leben in der Tiefsee bei den mikroskopischen Kinorhyncha und Loricifera ultastrukturell geprüft werden. Elektronenmikroskopische Arbeiten bei Kinorhyncha, Loricifera und Brachiopoda tragen zudem dazu bei, die Evolution dieser Tiergruppen besser zu verstehen.
We present the δ11B of well-preserved brachiopod fossils coupled with geochemical modeling to examine how seawater boron responded to abrupt and dynamic climate changes in the Late Paleozoic. The Late Carboniferous, a time of major coal formation and glacio-eustatic sea level changes, is characterized by relatively stable brachiopod δ11B of 15-17‰, similar to values seen in modern brachiopods. Brachiopod δ11B dropped by ~5‰ in the early Permian and then re-stabilized at a new value of 10‰ within a few million years. Mass balance models of seawater δ11B reproduced the overall trends in our brachiopod data but failed to capture the large drop in δ11B in the early Permian. Published seawater 87Sr/86Sr and δ44/40Ca data based on brachiopod shells also shift to lower values in the early Permian, suggesting a common control on all three seawater isotope systems. The Permian terrestrial record of evaporites and eolian deposits suggests a prolonged reduced delivery of dissolved weathering products to the ocean, accounting for the change in seawater 87Sr/86Sr. This reduced weathering, in turn, led to increased atmospheric CO2 and lowered seawater pH, which may have significantly decreased major removal mechanisms for seawater calcium and boron leading to declines in both isotope systems. We propose that boron removal via coprecipitation in carbonates and adsorption onto clay minerals was significantly diminished due to a reduction in the availability of the borate aqueous species caused by lowered seawater pH.
To evaluate the isotopic record of climate change and carbon sequestration in the Late Paleozoic, we have compiled new and published oxygen and carbon isotopic measurements of more than 2000 brachiopod shells from Carboniferous through Middle Permian (359-260 Ma) strata worldwide. We focus on the isotopic records from the U.S. Midcontinent and the Russian Platform because these two regions provide well-preserved marine fossils spanning a broad time interval.
Brachiopod shells were processed and screened for diagenesis by different methods depending on the research group. Some groups crush shells and pick clear crystals under the microscope. Five to ten milligrams of Ca carbonate are analyzed for trace and minor elements (Mg, Sr, Fe, Mn). Other research groups thin-section shells and use cathodoluminscence and plane light microscopy to screen for diagenesis. Nonluminescent shell is microsampled (0.05-0.1 mg) on the thin-section or complementary billet. All research groups use isotope ratio mass spectrometer for carbon (13C/12C) and oxygen (18O/16O) analyses. These data are used to examine paleotemperatures and their relation to climate in the past.