ALBERT

Description: Studies investigating the effect of increasing CO2 levels on the phosphorus cycle in natural waters are lacking although phosphorus often controls phytoplankton development in many aquatic systems. The aim of our study was to analyse effects of elevated CO2 levels on phosphorus pool sizes and uptake. The phosphorus dynamic was followed in a CO2-manipulation mesocosm experiment in the Storfjärden (western Gulf of Finland, Baltic Sea) in summer 2012 and was also studied in the surrounding fjord water. In all mesocosms as well as in surface waters of Storfjärden, dissolved organic phosphorus (DOP) concentrations of 0.26 ± 0.03 and 0.23 ± 0.04 µmol L−1, respectively, formed the main fraction of the total P-pool (TP), whereas phosphate (PO4) constituted the lowest fraction with mean concentration of 0.15 ± 0.02 in the mesocosms and 0.17 ± 0.07 µmol L−1 in the fjord. Transformation of PO4 into DOP appeared to be the main pathway of PO4 turnover. About 82 % of PO4 was converted into DOP whereby only 18 % of PO4 was transformed into particulate phosphorus (PP). PO4 uptake rates measured in the mesocosms ranged between 0.6 and 3.9 nmol L−1 h−1. About 86 % of them was realized by the size fraction  1000 µatm during periods when phytoplankton biomass increased. In addition, we found significant relationships (e.g., between PP and Chl a) in the untreated mesocosms which were not observed under high fCO2 conditions. Consequently, it can be hypothesized that the relationship between PP formation and phytoplankton growth changed with CO2 elevation. It can be deduced from the results, that visible effects of CO2 on P pools are coupled to phytoplankton growth when the transformation of PO4 into POP was stimulated. The transformation of PO4 into DOP on the other hand does not seem to be affected. Additionally, there were some indications that cellular mechanisms of P regulation might be modified under CO2 elevation changing the relationship between cellular constituents.

Description: The availability of dissolved iron (dFe) exerts an important control on primary production. Recent ocean observation programs have provided information on dFe in many parts of the ocean, but knowledge is still limited concerning the rates of processes that control the concentrations and cycling of dFe in the ocean and hence the role of dFe as a determinant of global primary production. We constructed a three-dimensional gridded dataset of oceanic dFe concentrations by using both observations and a simple model of the iron cycle, and estimated the difference of processes among the ocean basins in controlling the dFe distributions. A Green's function approach was used to integrate the observations and the model. The reproduced three-dimensional dFe distribution indicated that iron influx from aeolian dust and from shelf sediment were 7.6 Gmol yr and 4.4 Gmol yr in the Atlantic Ocean and 0.4 Gmol yr and 4.1 Gmol yr in the Pacific Ocean. The residence times were estimated to be 12.2 years in the Atlantic and 80.4 years in the Pacific. These estimates imply large differences in the cycling of dFe between the two ocean basins that would need to be taken into consideration when projecting future iron biogeochemical cycling under different climate change scenarios. Although there is some uncertainty in our estimates, global estimates of iron cycle characteristics based on this approach can be expected to enhance our understanding of the material cycle and hence of the current and future rates of marine primary production.

Description: Plastic pollution has become a widespread problem affecting multiple environmental compartments, with associated chemicals having harmful effects on living organisms. Here, we developed a Target Plastic Model (TPM) to estimate the critical plastic burden of various toxicants in five types of plastics, namely polydimethylsiloxane (PDMS), polyoxymethylene (POM), polyacrylate (PA), low-density polyethylene (LDPE), and polyurethane ester (PU), following the Target Lipid Model (TLM) framework. The critical plastic burdens of baseline (n=115), less-inert (n=73), and reactive (n=75) toxicants ranged from 0.17-51.33, 0.04-26.62, and 1.00 × 10^-6 - 6.78 × 10^-4 mmol/kg of plastic, respectively. While critical plastic burdens were also estimated for other plastic phases, such as polypropylene (PP), polystyrene (PS), polyvinyl chloride (PVC), ultra-high molecular weight polyethylene (UHMWPE), and high-density polyethylene (HDPE), the findings were less reliable due to a lack of experimental data. Our study showed that PDMS, PA, POM, PE, and PU are similar to biomembranes in mimicking the exchange of chemicals with the water phase. Using the TPM, median lethal concentration (LC50) values for fish exposed to baseline toxicants were predicted, and the results agreed with experimental values, with RMSE ranging from 0.311-0.538 log unit. For less inert chemicals, predictions were within a factor of 5 of experimental values. The TPM's performance was comparable to other widely used models, such as the TLM, ECOSAR, and Abraham Solvation Model. However, like other models, TPM was not effective in predicting the toxicities of reactive toxicants, with RMSE exceeding 1 log unit. TPM can provide valuable insights into the toxicities of chemicals associated with environmental plastic phases, assisting in selecting the best polymeric phase for passive sampling and designing better passive dosing techniques for toxicity experiments. Moreover, TPM can assist in selecting the best plastic phase for developing animal alternatives for toxicity measurement and determining the toxicity of complex mixtures such as those arising during oil spills.

Description: GEOTRACES SO298 "Equatorial Pacific GEOTRACES GP11", 14.04. - 02.06.2023, Guayaquil (Ecuador) - Townsville (Australien)

Description: GEOTRACES SO298 "Equatorial Pacific GEOTRACES GP11", 14.04. - 02.06.2023, Guayaquil (Ecuador) - Townsville (Australien)

Description: GEOTRACES SO298 "Equatorial Pacific GEOTRACES GP11", 14.04. - 02.06.2023, Guayaquil (Ecuador) - Townsville (Australien)

Description: GEOTRACES SO298 "Equatorial Pacific GEOTRACES GP11", 14.04. - 02.06.2023, Guayaquil (Ecuador) - Townsville (Australien)

Description: GEOTRACES SO298 "Equatorial Pacific GEOTRACES GP11", 14.04. - 02.06.2023, Guayaquil (Ecuador) - Townsville (Australien)

Description: GEOTRACES SO298 "Equatorial Pacific GEOTRACES GP11", 14.04. - 02.06.2023, Guayaquil (Ecuador) - Townsville (Australien)