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Coastal circulations driven by river outflow in a variable-density 1.5-layer model

DRS at CSIR-National Institute of Oceanography

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Title Coastal circulations driven by river outflow in a variable-density 1.5-layer model
 
Creator McCreary, J.P.
Zhang, S.
Shetye, S.R.
 
Subject shell dynamics
outflow
plumes
pycnocline
mathematical models
 
Description A variable-density, 1.5-layer model is used to investigate the dynamics of the fresher-water plumes generated by river outflow. Solutions are found in a north-south channel, and the transport M sub(tau) and salinity S sub(tau) of the outflow are specified as boundary conditions along a 25 km-wide segment of the western boundary. In most cases, the river water discharges into a preexisting, oceanic mixed layer with thickness H sub(1). When M sub(tau) is sufficiently low, plumes remain coastally trapped. Immediately after the outflow is switched on, a coastal Kelvin wave is excited at the river mouth that establishes a southward current of oceanic water along the right-hand coast. In contrast, all the river water first bends to the left as it exits the river mouth, and the resulting plume advances northward along the left-hand coast. At the plume nose, some of the fresher water reverses direction, and this water, together with some oceanic water, flows southward on either side of the offshore density front between the fresher and salty waters. Two processes cause this upstream movement: geostrophic adjustment generates the southward frontal current, and Kelvin-wave propagation from the nost thins the layer within the plume thereby establishing the northward, geostrophic, coastal jet. When M sub(tau) is sufficiently high, coastally trapped plumes no longer exist. If the Rossby number of the outflow is also large enough, the river water flows directly offshore and only a portion of it recirculates to form a northward propagating coastal plume. The angle at which the outflow leaves the river mouth becomes more southward as M sub(tau) and S sub(tau) increase and as H sub(1) decreases. The strength of the northward propagating plume is weakened as H sub(1) decreases and S sub(tau) increases. When H sub(tau) = 0 so that there is no ambient oceanic layer, there is no northward plume at all. Likewise, the plume is weakened when the model includes entrainment, a process that acts to prevent the layer thickness from thinning appreciably
 
Date 2009-01-12T09:29:32Z
2009-01-12T09:29:32Z
1997
 
Type Journal Article
 
Identifier Journal of Geophysical Research (C: Oceans), Vol.102; 15535-15554p.
http://drs.nio.org/drs/handle/2264/2082
 
Language en
 
Rights Copyright [1997]. All efforts have been made to respect the copyright to the best of our knowledge. Inadvertent omissions, if brought to our notice, stand for correction and withdrawal of document from this repository.
 
Publisher American Geophysical Union