Abstract
The numerical simulation of estuarine dynamics requires accurate prediction for the transport of tracers, such as temperature and salinity. During the simulation of these processes, all the numerical models introduce two kinds of tracer mixing: 1) by parameterizing the tracer eddy diffusivity through turbulence models leading to a source of physical mixing and 2) discretization of the tracer advection term that leads to numerical mixing. Physical and numerical mixing both vary with the choice of horizontal advection schemes, grid resolution, and time step. By simulating four idealized cases, this study compares the physical and numerical mixing for three different tracer advection schemes. Idealized domains only involving physical and numerical mixing are used to verify the implementation of mixing terms by equating them to total tracer variance. Among the three horizontal advection schemes, the scheme that causes the least numerical mixing while maintaining a sharp front also results in larger physical mixing. Instantaneous spatial comparison of mixing components shows that physical mixing is dominant in regions of large vertical gradients, while numerical mixing dominates at sharp fronts that contain large horizontal tracer gradients. In the case of estuaries, numerical mixing might locally dominate over physical mixing; however, the amount of volume integrated numerical mixing through the domain compared to integrated physical mixing remains relatively small for this particular modeling system.
Highlights
Estuaries provide critical habitat to sustain marine life
The current paper estimates the two sources of tracer mixing: physical mixing originating from the turbulence closure model and numerical mixing originating from discretization methods, with a focus on an estuarine environment using the Coupled Ocean-Atmosphere-Wave-Sediment Transport (COAWST) modeling system
The formulation of physical and numerical mixing terms in the model is verified in test cases 1 and 2, respectively, by comparing the time and volume integrated total mixing that amounts to total tracer variance decay
Summary
Estuaries provide critical habitat to sustain marine life. The transport of tracer quantities, such as salinity, sediment, plankton, nutrients, and pollutants, are crucial factors that determine the quality and sustainability of estuaries. The salinity is an important dynamical variable in estuaries, such that the mixing of saline water with fresh water has important consequences for estuarine circulation and stratification [1] These interactions of mixing and stratification can depend on several factors such as the size, depth, forcing characteristics, river inflow [2], ocean salinity, tidal forcing and wind forcing [3,4]. Other lower order models parameterize the role of mixing with eddy coefficients which depend on the strength of the tidal velocity [3,16,17] They solve for tidally averaged momentum and salinity equations in a rectangular estuary with two vertically averaged levels. These works highlight the importance of further exploring the dynamical balances in estuarine dynamics to get a better estimate of mixing of tracers such as salinity
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
