Final Report Summary - STORM (Stemming the rising tide: The protective role of saltmarshes)
Over the past 24 months we have achieved most of our project goals.
1) We have successfully constructed and executed an elevated CO2 experiment, which measured how elevated CO2 and eutrophication would impact vertical accretion rates in saltmarshes. We found a significant, positive, influence of elevated CO2 on vertical accretion in vegetated coastal habitats and, using boosted regression modelling, identified a number of factors contributing to this, namely decomposition rates, root growth and plant water use (Reef et al. 2016). We have also identified a key role for the grass Puccinellia maritima in encouraging vertical accretion. Puccinelllia maritima is a climate sensitive and grazing sensitive species and our results can be used to guide management policy regarding the conservation of saltmarshes in the face of sea level rise. The mesocosm study identified a significant change in canopy morphology with eutrophication and elevated CO2 and the impact of such changes on surface accretion was addressed in experiment 3.
2) Field campaigns planned at both Tillingham (Essex) and Donna Nook (Lincolnshire) saltmarshes have been completed over the two-year period. Our fieldwork allowed us to measure the biological components (root growth and decomposition) of vertical accretion for both the winter and summer season (manuscript #1 in advanced stages of preparation). Our study suggest a significant, previously overlooked gain to marsh elevation by biological contributions. In this component of the study we find that there is a spatio-temporal variation in the contribution of belowground biological processes to surface accretion on saltmarshes, ranging from a vertical gain of 1.6 mm/y in the upper marsh in the summer to 0.3 mm/y in the lower marsh in the winter. Using a UAV survey, we are able to identify the marsh zones and apply the correct biological contribution to an entire foreshore for the summer and the winter season.