Abstract
The hydrodynamic characteristics of small, intertidal perimeter habitats make flushing and residence times in these environments difficult to quantify using conventional approaches. The flooding and draining of intertidal shallows surrounding small perimeter sloughs result in large volume changes relative to total system volume during each tidal cycle. In such environments, an Eulerian framework of flushing and residence time may not be the best approach for quantifying tidal exchange; thus, alternative approaches should be considered in analyzing hydrodynamic exchange in small perimeter habitats. In this study, the results of applying such an approach to a small intertidal perimeter slough in South San Francisco Bay are presented. Previous work has shown that hydrodynamic exchange in an estuarine system can be analyzed by making Eulerian measurements of hydrodynamic fluxes and binning them according to salinity and temperature classes, thus providing a quasi-Lagrangian method of analyzing exchange and transport in an estuarine system. We apply a method which uses this approach to estimate the volumetric exchange ratio M, which is used to estimate the tidal exchange within an estuary during each tidal cycle. We find that the estimation of volumetric exchange ratios and the calculation of hydrodynamic residence times in estuarine systems can be complicated by mixing conditions associated with very strong tidal forcing, particularly in small-volume systems such as small perimeter sloughs, where the tidal prism can be on the scale of or greater than the total system volume.
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Acknowledgments
The authors would like to thank Andreas Brand, Susan Willis, and Wayne Wagner for their help in the field data collection at Palo Alto Baylands. This project was funded by UC-National Labs Funding Program, the National Science Foundation, and the California Coastal Conservancy.
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Hsu, K., Stacey, M.T. & Holleman, R.C. Exchange Between an Estuary and an Intertidal Marsh and Slough. Estuaries and Coasts 36, 1137–1149 (2013). https://doi.org/10.1007/s12237-013-9631-2
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DOI: https://doi.org/10.1007/s12237-013-9631-2