Desalination
brine is a hypersaline byproduct that contains various
operational chemicals such as polyphosphonate-based antiscalants.
Brine often sinks and flows over the seabed by density currents; therefore,
it may affect sediment-water nutrient fluxes and thus microbial activity.
We quantified these parameters in brine plumes around two large-scale
desalination facilities located in the P-limited Southeastern Mediterranean
Sea. The benthic nutrient fluxes and microbial activity were determined
using ex-situ core benthocosms, to which we added
brine from the dispersion area in excess salinities of ∼3%
and 5% above natural levels. A higher influx of dissolved organic
phosphorus (∼6-fold) and an efflux of dissolved organic carbon
(∼1.7-fold) were measured in the brine-amended cores relative
to the controls. This was accompanied by increased oxygen consumption
(15%) and increased microbial activity (∼1.5–6.5-fold).
Field observations support the results from experimental manipulations,
yielding ∼4.5-fold higher microbial activity rates around the
brine plume compared to uninfluenced locations. Our results imply
that desalination brine can alter sedimentary processes affecting
benthic nutrients inventories. Moreover, we show that brine acts as
a vector of anthropogenic P, stimulating microbial activity in the
sediment–water interface.
The ratio of sodium to calcium in the shells of foraminifera (Na/Cashell) has been experimentally calibrated as a proxy for past ocean Ca concentrations (Hauzer et al., 2018, https://doi.org/10.1016/j.epsl.2018.06.004). In parallel, it has been suggested that Na/Cashell could be used as a proxy for paleo‐salinity. In this study, we determined the extent to which foraminiferal Na/Ca (and other elements) change with salinity for the shallow‐dwelling large benthic foraminifer Operculina ammonoides, an extant relative of the abundant Eocene Nummulites. The culture experiment was conducted under four salinities between 33 and 43 psu. Shell chemistry was measured by LA‐ICPMS with the newly precipitated CaCO3 identified by a 135Ba‐spike added to the experimental seawater. Na/Cashell, Mg/Cashell and Li/Cashell in O. ammonoides increased slightly with salinity, while Sr/Cashell showed no resolvable change. The change in Na/Cashell due to salinity was small (∼1.4%/psu) compared to the changes in this ratio caused by varying seawater calcium concentrations (Casw) with a sensitivity of ∼5%/(mmol kg−1) Casw. Moreover, the change in salinity in most regions of the past open oceans is minor compared to the large secular variations in Casw during the Phanerozoic (10–40 mmol kg−1). Thus, if at all, paleo‐salinity may be reconstructed based on Na/Cashell only for samples younger than Casw residence time (∼1 Myr). Furthermore, both regional and global changes in ocean salinity over geological time do not pose a significant complication for the use of Na/Cashell as a proxy for past changes in seawater calcium concentrations.
This communication describes the bionic preparation of a composite material in which fluorescent magnetite nanoparticles are included within the calcitic skeletal structure of the foraminifer Amphistrigina lessoni.
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