Abstract
Residence times of dissolved substances and sedimentation rates in tidal channels are affected by residual (tidally averaged) circulation patterns. One influence on these circulation patterns is the longitudinal density gradient. In most estuaries the longitudinal density gradient typically maintains a constant direction. However, a junction of tidal channels can create a local reversal (change in sign) of the density gradient. This can occur due to a difference in the phase of tidal currents in each channel. In San Francisco Bay, the phasing of the currents at the junction of Mare Island Strait and Carquinez Strait produces a local salinity minimum in Mare Island Strait. At the location of a local salinity minimum the longitudinal density gradient reverses direction. This paper presents four numerical models that were used to investigate the circulation caused by the salinity minimum: (1) A simple one-dimensional (1D) finite difference model demonstrates that a local salinity minimum is advected into Mare Island Strait from the junction with Carquinez Strait during flood tide. (2) A three-dimensional (3D) hydrodynamic finite element model is used to compute the tidally averaged circulation in a channel that contains a salinity minimum (a change in the sign of the longitudinal density gradient) and compares that to a channel that contains a longitudinal density gradient in a constant direction. The tidally averaged circulation produced by the salinity minimum is characterized by converging flow at the bed and diverging flow at the surface, whereas the circulation produced by the constant direction gradient is characterized by converging flow at the bed and downstream surface currents. These velocity fields are used to drive both a particle tracking and a sediment transport model. (3) A particle tracking model demonstrates a 30 percent increase in the residence time of neutrally buoyant particles transported through the salinity minimum, as compared to transport through a constant direction density gradient. (4) A sediment transport model demonstrates increased deposition at the near-bed null point of the salinity minimum, as compared to the constant direction gradient null point. These results are corroborated by historically noted large sedimentation rates and a local maximum of selenium accumulation in clams at the null point in Mare Island Strait.
Highlights
The transport and residence times of dissolved constituents and suspended sediment in estuarine waters are influenced by residual circulation patterns
Four types of numerical simulations were used in this study: (1) a 1D nite di erence model to demonstrate the formation of a local salinity minimum in Mare Island Strait, (2) a 3D nite element model to compare the tidally averaged current structure from a salinity minimum to a constant direction gradient, (3) a particle tracking model to quantify residence times, and (4) a sediment transport model to reveal the increased deposition rates associated with the circulation caused by the salinity minimum circulation
The salinity minimum circulation (Figure 5c) consists of near-bed velocities that converge from either side of the salinity minimum to meet at a null point that develops near y = 3km
Summary
The transport and residence times of dissolved constituents and suspended sediment in estuarine waters are influenced by residual (tidally averaged) circulation patterns These circulation patterns are controlled by such factors as tidal currents interacting with the geometry, bathymetry, wind, geophysical rotation, freshwater inflow, and the balance between barotropic (water surface) and baroclinic (density) pressure gradients. Warner, et al (2002) report that a local salinity (density) minimum develops due to the tidal current phasing and salt transport that occurs at the junction of two tidal channels, Mare Island Strait and Carquinez Strait, in northern San Francisco Bay, California. Mare Island Strait receives an increasing salinity when Carquinez Strait floods This tidal phase difference creates the local salinity minimum in Mare Island Strait during each tidal cycle. Because the tidal prism in Mare Island Strait is less than one-tenth the size of that in Carquinez Strait, the phasing e ect produces a pronounced salinity minimum in Mare Island Strait, but has minor in uence on salinity in Carquinez Strait
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