Description: The upwelling area off North-West Africa is characterized by high export production, high nitrate and low oxygen concentration in bottom waters. The underlying sediment consists of sands that cover most of the continental shelf. Due to their permeability sands allow for fast advective pore water transport and can exhibit high rates of nitrogen (N) loss via denitrification as reported for anthropogenically eutrophied regions. However, N loss from sands underlying naturally eutrophied waters is not well studied, and in particular, N loss from the North-West African shelf is poorly constrained. During two research cruises in April/May 2010/2011, sediment was sampled along the North-West African shelf and volumetric denitrification rates were measured in sediment layers down to 8 cm depth using slurry incubations with 15N-labeled nitrate. Areal N loss was calculated by integrating volumetric rates down to the nitrate penetration depth derived from pore water profiles. Areal N loss was neither correlated with water depth nor with bottom water concentrations of nitrate and oxygen but was strongly dependent on sediment grain size and permeability. The derived empirical relation between benthic N loss and grains size suggests that pore water advection is an important regulating parameter for benthic denitrification in sands and further allowed extrapolating rates to an area of 53,000 km2 using detailed sediment maps. Denitrification from this region amounts to 995 kt yr-1 (average 3.6 mmol m-2 d-1) which is 4 times higher than previous estimates based on diffusive pore water transport. Sandy sediments cover 50-60% of the continental shelf and thus may contribute significantly to the global benthic N loss.

Description: Summary A detailed multi-disciplinary research program was conducted at the Mauritanian oxygen minimum zone (OMZ). Investigations were primarily performed along a depth transect at 18°20’ N. In this area upwelling of cold, nutrient-rich deep water is strongly seasonal, predominating from April until December. Major aim was to advance understanding of how OMZs are maintained and to determine feedbacks of benthic nutrient release on the currently expanding Mauritanian OMZ under such conditions. Major focus was on (i) variability of benthic nutrient release in response to hydrodynamic forcing and regional differences in geochemistry, (ii) diapycnal and advective fluxes of nutrients, trace metals, and radio-tracer between the sediments and the stratified interior ocean as well as their entrainment into the surface mixed layer and (iii) processes involved in the respective benthic and pelagic N, Fe, and P cycles. The working program in the water column comprised a total of 73 CTD casts, 38 microstructure CTD- and 17 in situ pump deployments. Moorings and Glider were deployed at 18°20’ N and 19°50’ N. Furthermore, in the northern working area ADCP-transects and casts of Underway CTDs were conducted to follow upwelling-induced frontal systems. In situ benthic fluxes of nutrients and oxygen were conducted using the Biogeochemical Observatories BIGO I and BIGO II comprising a total of 9 deployments. Further sediment samples for biogeochemical, investigations were obtained during the deployment of 22 casts of a video guided Multiple Corer (MUC). All deployments were successful and the envisaged data and samples were collected.

Description: The magnitude of nutrient and trace metal release from oxygen minimum zone (OMZ) sediments as well as their fate in the water column is of utmost importance for the pelagic nutrient budget and consequently for the ongoing expansion of OMZs. The major aim of this research cruise that was conducted within the framework of the Kiel collaborative research center SFB 754 (Climate – Biogeochemistry Interactions in the Tropical Ocean), was to study the effects of variable environmental conditions on benthic element turnover and exchange with the bottom water under natural conditions of austral fall/winter but also during experiments. This allows the quantitative simulation of benthic-pelagic nutrient- and trace metal budgets over longer time periods. The experimental investigations aimed to specifically resolve the contribution of sulfur bacteria and denitrifying foraminifera controlling benthic N, P and S fluxes. The investigation of mixing processes in the bottom boundary layer (BBL) and quantification of diapycnal and advective fluxes across the BBL and the stratified water column will be used to resolve the fate of these substances. The multidisciplinary study mainly focused on a depth transect at 12°S and is scientifically closely linked to the METEOR cruises M135, M136 and M138. In order to achieve the scientific goals an intense physical, biogeochemical and biological working program was conducted in the water column and at the seafloor accompanied by shipboard experiments. Studies in the water column comprised 92 CTD, 65 microstructure CTD, 18 TM-CTD and 14 in situ pump deployments. Sediment samples were obtained during 47 mulitple-corer and 12 Lander deployments. Additionally, lander deployments were performed to obtain time series of physical parameters and the current regime in water depths of 76 and 128m. The deployment of these instruments covered the time period of cruises M136 and M137. We slightly deviated from the cruise proposal and spent a minor amount of the station time along a zonal transect at 12.3°S in order study the biogeochemistry during eddy formation. Eddy formation cannot be predicted and hence planned in a cruise proposal, however their study bears a high scientific potential and is a central part of the SFB745 research activities. Due to the good weather conditions all deployments were successful, hence all the data and sample material aimed for has been achieved. It is to expect that as planned all scientific questions can be addressed. Especially, the joined synthesis including the data of the other recent SFB cruises M135, M136 und M138 and their comparison with the earlier SFB-cruises M77, M92 harbor a high scientific potential.