Abstract
The flow of terrestrial carbon to rivers and inland waters is a major term in the global carbon cycle. The organic fraction of this flux may be buried, remineralized or ultimately stored in the deep ocean. The latter can only occur if terrestrial organic carbon can pass through the coastal and estuarine filter, a process of unknown efficiency. Here, data are presented on the spatial distribution of terrestrial fluorescent and chromophoric dissolved organic matter (FDOM and CDOM, respectively) throughout the North Sea, which receives organic matter from multiple distinct sources. We use FDOM and CDOM as proxies for terrestrial dissolved organic matter (tDOM) to test the hypothesis that tDOM is quantitatively transferred through the North Sea to the open North Atlantic Ocean. Excitation emission matrix fluorescence and parallel factor analysis (EEM-PARAFAC) revealed a single terrestrial humic-like class of compounds whose distribution was restricted to the coastal margins and, via an inverse salinity relationship, to major riverine inputs. Two distinct sources of fluorescent humic-like material were observed associated with the combined outflows of the Rhine, Weser and Elbe rivers in the south-eastern North Sea and the Baltic Sea outflow to the eastern central North Sea. The flux of tDOM from the North Sea to the Atlantic Ocean appears insignificant, although tDOM export may occur through Norwegian coastal waters unsampled in our study. Our analysis suggests that the bulk of tDOM exported from the Northwest European and Scandinavian landmasses is buried or remineralized internally, with potential losses to the atmosphere. This interpretation implies that the residence time in estuarine and coastal systems exerts an important control over the fate of tDOM and needs to be considered when evaluating the role of terrestrial carbon losses in the global carbon cycle.
Highlights
This study revealed the Rhine-Meuse-Scheldt delta to be a major source of NO3− and DON to the southern North Sea
The Weser/Elbe and Baltic Sea outflows were a significant source of DOP but not PO43−
Elevated concentrations of PO43− and DOP were observed around Northern Scotland, possibly due to upwelling or North Atlantic inflows collecting tDOM from neighbouring islands or from the Scottish mainland
Summary
The flow of terrestrial organic matter (tOM) through aquatic ecosystems is a significant and increasing component of the global carbon cycle (Ciais et al, 2013) and appears to be increasing in some regions, notably Northern Europe (Monteith et al, 2007). A total global carbon (C) flux from the land to the ocean of approximately 0.9 Pg C occurs annually consisting of ~0.2 Pg as dissolved organic carbon (DOC), 0.3 Pg as dissolved inorganic carbon (DIC) and up to 0.4 Pg as particulate organic carbon (POC) (Bianchi, 2011; Dai et al, 2012; Ciais et al, 2013). Estimates vary widely for the various carbon pools, but for the UK it has been estimated that N70% of soil derived DOC entering inland waterways is respired or otherwise lost before it reaches coastal waters (Worrall et al, 2012), which is similar to a global estimate of total organic carbon removal in inland waters obtained by Tranvik et al (2009). CDOM and FDOM represent 20–70% of the overall DOM pool (e.g. Dittmar and Stubbins, 2014), and as tracers of the tDOM pool can underestimate export fluxes, but CDOM and FDOM distributions are considered valuable proxies for tDOM more generally (e.g. Stedmon and Nelson, 2015)
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