Degradability and remineralization of peat-derived terrestrial dissolved organic carbon in the Sunda Shelf Sea

Abstract

The remineralization of terrestrial dissolved organic carbon (tDOC) plays an important role in coastal carbon and nutrient cycling, and can affect primary productivity and seawater pH. However, the fate of tDOC in the ocean remains poorly understood. Southeast Asia’s Sunda Shelf Sea receives around 10% of global tDOC input from peatland-draining rivers. Here, we performed photodegradation and long-term (2 months to 1.5 years) biodegradation experiments with samples from peatland-draining rivers and from peat tDOC-rich coastal water. We used the resulting photochemical and microbial decay rates to parameterize a 1-dimensional model simulation. This indicates that 24% and 23% of the initial tDOC entering the Sunda Shelf can be remineralized from pure photo- and pure biodegradation, respectively, after 2 years (which represents an upper limit of seawater residence time on the Sunda Shelf). We also show for the first time that the biodegradation rate of Southeast Asian peat tDOC is enhanced by prior photodegradation. Accounting for this additional photo-influenced biodegradation in our model simulation causes an additional 16% of the initial tDOC remineralized. Our results suggest a notably higher contribution of photodegradation compared to other ocean margins, due to the combination of low pure biodegradation rate, high solar irradiance, relatively long water residence time on the Sunda Shelf, and the photo-enhancement of the biodegradation rate.