In the first year of work, data from previous projects were incorporated into a new journal article draft, which was published in Applied Geochemistry that same year. As well, initial results were presented at the International Association of Hydrogeologists (IAH) 2017 Annual Meeting in Dubrovnik, Croatia. Another publication draft, with the Marie Curie recipient as contributing author, was completed for publication the following year in Hydrological Processes (van Geldern et al. 2018). In addition, preparations were made for fieldwork intended for the following year. This entailed preliminary analyses of existing datasets to help plan sampling schemes, and the establishment of selected rivers and springs for water collection.
The following year, a fieldwork campaign was carried out based on these plans, to obtain new data pertaining to carbon cycling in springs and karstic headwaters. This was carried out in 6 separate excursions between the months of February and November in order to discern seasonal trends in dissolved/particulate carbon fluxes and CO2 outgassing. For this work, water samples were analyzed for 13C and concentrations of dissolved organic and inorganic carbon (DOC/DIC) and particulate organic carbon (POC), and CO2 effluxes were measured with sensors installed in static chambers. Initial findings from the headwater sampling campaign was presented at another conference in September, the IAH 2018 Annual Meeting in Daejeon, South Korea (September 9-14, 2018). As well, data from an ancillary project, concerned with the quantification of nitrate fluxes in the Pegnitz River and determination of wastewater contributions, was presented as a poster at the European Geosciences Union (EGU) 2018 Meeting in Vienna (April 8-13, 2018).
An associated MSc thesis completed by Maxmilian Schmidt was also successfully completed, which incorporated some data from the 2018 fieldwork campaign. The findings from this thesis will be used to plan projected future work that will extend our research on CO2 outgassing from karstic springs, with focus on CO2 emissions within the first 200 metres of source springs. This new research will determine the gradient of CO2 outgassing within river headwaters, which may constitute the bulk of CO2 loss in a given basin. A related proposal has already been incorporated into a DFG grant for review. If successful, this grant will extend our work for another 3 years.