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Abstract
Ecosystem engineers that inhabit coastal and estuarine environments, such as reef building oysters, do not only stabilise the sediment within their reefs, but their influence might also extend far outside their reefs, affecting tidal flat morphology and protecting the surrounding soft-sediment environment against erosion. However, quantitative information is largely missing, and the spatially extended ecosystem engineering effects on the surrounding soft-sediment largely unstudied. To quantify this, we measured elevations around eleven naturalCrassostrea gigas reefs occurring on tidal flats in the Oosterschelde estuary (the Netherlands). These tidal flats experience strong erosion as a consequence of human interventions in the system. Various reef sizes were chosen to test the proportional effects of reefs on tidal flat morphology. Measurements were used to create 3-dimensional surface maps to obtain properties of the reefs and the surrounding soft-sediment environment. The area of the oyster reefs ranged from 2 to 1,908 m2. Reef length varied between 1 and 61 m, reef width between 1 and 45 m, and reef height between 0.20 and 1.08 m. Reefs varied in shape, going from round shape structures to more elongated ones. We observed elevated areas (>5 cm elevation from the background intertidal slope) on the lee side of all reefs, caused by the interaction between the reef’s structure and locally prevailing wave conditions. The elevated area (i.e. the spatially extended ecosystem engineering effect) affected by the reef was of the same order of magnitude as the reef area. The elevated area was related to reef properties such as reef length, width, and height. Reef length, however, appeared to be the best predictor. These findings contribute to management solutions for coastal adaptation and protection. Our study clearly showed that oyster reefs not only protect the tidal flat under their footprint, but as well an area beyond the boundary of the reef.
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Acknowledgments
The work presented in this paper was carried out as part of the innovation program, Building with Nature, which is funded from several sources, including the Subsidieregeling Innovatieketen Water (Staatscourant No. 953 and 17009), sponsored by the Dutch Ministry of Transport, Public Works, and Water Management, and partner contributions by the participants of the EcoShape Foundation. EcoShape receives cofunding from the European Fund for Regional Development and the municipality of Dordrecht. We thank Raak Pro Building with Living Nature for gathering the data and the Royal Netherlands Institute for Sea Research for providing DGPS devices. Special thanks go to Prof. Dr. P.M.J. Herman for his valuable comments that improved the manuscript.
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IMARES Wageningen, Institute for Marine Resources and Ecosystem Studies, Yerseke, The Netherlands
Brenda Walles, Tom Ysebaert & Aad C. Smaal
Aquaculture and Fisheries Group, Wageningen University and Research, Wageningen, The Netherlands
Brenda Walles & Aad C. Smaal
Delta Academy Applied Research Centre, HZ University of Applied Sciences, Vlissingen, The Netherlands
João Salvador de Paiva
Spatial Ecology Department, NIOZ Yerseke, Royal Netherlands Institute for Sea Research, Yerseke, The Netherlands
Tom Ysebaert
Faculty of Civil Engineering and Geosciences, Delft University of Technology, Delft, The Netherlands
Bram C. van Prooijen
- Brenda Walles
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Walles, B., Salvador de Paiva, J., van Prooijen, B.C.et al. The Ecosystem EngineerCrassostrea gigas Affects Tidal Flat Morphology Beyond the Boundary of Their Reef Structures.Estuaries and Coasts38, 941–950 (2015). https://doi.org/10.1007/s12237-014-9860-z
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