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1. Ebullition of oxygen from seagrasses under supersaturated conditions

   https://doi.org/10.1002/lno.11299  

   Long, Matthew H.; Sutherland, Kevin; Wankel, Scott D.; Burdige, David J.; Zimmerman, Richard C. (August 2019, Limnology and Oceanography)
2. Mudflat Biostabilization Alters Coastal Landscape Sediment Connectivity

   https://doi.org/10.1029/2024JG008500  

   Valentine, K; Kirwan, M L (March 2025, Journal of Geophysical Research: Biogeosciences)

   Abstract Connectivity between adjacent ecosystems is thought to increase ecosystem resilience and function. In coastal ecosystems, the exchange of sediment and nutrients between mudflats and marshes is important for the long‐term dynamics of both systems. Mudflat morphodynamics are driven by the interaction of waves and sediment erodibility, which is a function of sediment type and the presence of biostabilizers such as microphytobenthos. However, there is a poor understanding about how the evolution of mudflats may impact the morphodynamics and function of adjacent salt marshes. Here, we use a Coastal Landscape Transect model connecting mudflats and marshes to investigate how microphytobenthos influence the coupled behavior of mudflats and marshes, and how that coupled behavior influences carbon storage. We find that biofilms reduce the connectivity between mudflats and marshes by reducing erodibility and sediment exchange. Reduced connectivity associated with microphytobenthos leads to a shallower mudflat and more carbon stored in the mudflat sediments, which in turn cascades to a higher combined marsh and mudflat carbon stock. Furthermore, our results highlight the role of connectivity across the coastal landscape and suggest that biostabilization leads to relatively small changes in morphodynamics but relatively large changes in ecosystem function. 

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3. Mud, Microbes, and Macrofauna: Seasonal Dynamics of the Iron Biogeochemical Cycle in an Intertidal Mudflat

   https://doi.org/10.3389/fmars.2020.562617  

   Beam, Jacob P.; George, Sarabeth; Record, Nicholas R.; Countway, Peter D.; Johnston, David T.; Girguis, Peter R.; Emerson, David (November 2020, Frontiers in Marine Science)
4. Data from: Measuring Estuarine Total Exchange Flow from Discrete Observations

   https://doi.org/10.6075/J0DJ5FS8  

   Lemagie_Emily, P; Giddings, Sarah N; MacCready, Parker; Seaton, Charles; Wu, Xiaodong (January 2025, UC San Diego Library Digital Collections)

   The two-way exchange of water and properties such as heat and salinity as well as other suspended material between estuaries and the coastal ocean is important to regulating these marine habitats. This exchange can be challenging to measure. The Total Exchange Flow (TEF) method provides a way to organize the complexity of this exchange into distinct layers based on a given water property. This method has primarily been applied in numerical models that provide high resolution output in space and time. The goal here is to identify the minimum horizontal and vertical sampling resolutions needed to measure TEF depending on estuary type. Results from three realistic hydrodynamic models were investigated. These models included three estuary types: bay (San Diego Bay: data/SDB_*.mat files), salt-wedge (Columbia River: data/CR_*.mat files), and fjord (Salish Sea: data/SJF_*.mat files). The models were sampled using three different mooring strategies, varying the number of mooring locations and sample depths with each method. This repository includes the Matlab code for repeating these sampling methods and TEF calculations using the data from the three estuary models listed above. 

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5. Measuring Estuarine Total Exchange Flow From Discrete Observations

   https://doi.org/10.1029/2022JC018960  

   Lemagie, E. P.; Giddings, S. N.; MacCready, P.; Seaton, C.; Wu, X. (October 2022, Journal of Geophysical Research: Oceans)

   Abstract The exchange between estuaries and the coastal ocean is a key dynamical driver impacting nutrient and phytoplankton concentrations and regulating estuarine residence time, hypoxia, and acidification. Estuarine exchange flows can be particularly challenging to monitor because many systems have strong vertical and lateral velocity shear and sharp gradients in water properties that vary over space and time, requiring high‐resolution measurements in order to accurately constrain the flux. The total exchange flow (TEF) method provides detailed information about the salinity structure of the exchange, but requires observations (or model resolution) that resolve the time and spatial co‐variability of salinity and currents. The goal of this analysis is to provide recommendations for measuring TEF with the most efficient spatial sampling resolution. Results from three realistic hydrodynamic models were investigated. These model domains included three estuary types: a bay (San Diego Bay), a salt‐wedge (Columbia River), and a fjord (Salish Sea). Model fields were sampled using three different mooring strategies, varying the number of mooring locations (lateral resolution) and sample depths (vertical resolution) with each method. The exchange volume transport was more sensitive than salinity to the sampling resolution. Most (>90%) of the exchange flow magnitude was captured by three to four moorings evenly distributed across the estuarine channel with a minimum threshold of 1–5 sample depths, which varied depending on the vertical stratification. These results can improve our ability to observe and monitor the exchange and transport of water masses efficiently with limited resources. 

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