Riverine Particulate Matter Enhances the Growth and Viability of the Marine Diatom Thalassiosira weissflogii

Riverine particulates dominate the transport of vital nutrients such as Si, Fe or P to the ocean margins, where they may increase primary production by acting as slow-release fertilizer. Furthermore, the supply of particulate surface area to the ocean is considered to be a major control of organic carbon burial. Taken together, these observations suggest a close link between the supply of riverine particulate material and the organic carbon cycle. To explore this link, we conducted microcosm experiments to measure the growth of the marine diatom Thalassiosira weissflogii in the presence and absence of different types and concentrations of riverine particulate material. Results demonstrate a strong positive effect of riverine particulate material on diatom growth with increased total diatom concentrations and slowed post-exponential death rates with increasing particulate concentration. Moreover, SEM and optical microscope investigations confirm that riverine particulates facilitate organic carbon burial through their role in the aggregation and sedimentation of phytoplankton. The supply of riverine particulate material has been shown to be markedly climate sensitive with their fluxes increasing dramatically with increasing global temperature and runoff. This pronounced climate sensitivity implies that riverine particulates contribute substantially in regulating atmospheric CO2 concentrations through their role in the organic carbon cycle.

Automated summary

Riverine particulates play a crucial role in transporting essential nutrients and affecting organic carbon burial in ocean margins. Microcosm experiments demonstrate the positive impact of riverine particulate material on diatom growth, as well as its role in organic carbon burial through aggregation and sedimentation of phytoplankton. The supply of riverine particulate material is highly sensitive to climate change and contributes significantly to regulating atmospheric CO2 concentrations.