<div dir="ltr"><br><b style="font-family:arial,helvetica,sans-serif">DATE:</b><span style="font-family:arial,helvetica,sans-serif"> Friday, October 11th, 2013</span><br><div class="gmail_quote"><div dir="ltr"><p><font face="arial, helvetica, sans-serif"><b>TITLE:</b> <span style="line-height:21px">Quantifying Impact of Climate Change on Reservoir Sedimentation</span></font></p>
<p><font face="arial, helvetica, sans-serif"><b>TIME:</b> <span><span>3:30 PM</span></span></font></p><p><font face="arial, helvetica, sans-serif"><b>LOCATION: </b> GMCS 214</font></p><p><font face="arial, helvetica, sans-serif"><b>SPEAKER:</b> <span style="line-height:21px">Dr. Svetlana Kostic. San Diego State University</span></font></p>
<p><span style="line-height:21px"><font face="arial, helvetica, sans-serif">Researchers predict that climate-fueled extreme weather events will continue to put many communities worldwide at increased risk for devastation from floods. FEMA estimates that areas at risk of flooding in the US would increase 45 percent by 2100, mainly due to climate change. A comprehensive numerical model of reservoir sedimentation is developed and used to assess the impact of flooding on reservoir performance. The model captures: a) the formation and evolution of the river-delta and associated deposits, and b) the morphodynamic effects of a dam at the downstream end of the reservoir. The outflow boundary condition is selected to emulate the release of flow over an uncontrolled or open-gate controlled spillway. The turbidity current is thus not allowed to vent until the underflow-clear water interface rises above the elevation of the overflow point. The model allows for a smooth and continuous progression from a stagnation to an overflow condition, which is a serious computational challenge. Two types of flood events are analyzed. First, a short, single-event turbidity current entering a reservoir is considered to demonstrate that the model reproduces, for the first time, all stages of the turbidity current propagation and interaction with the dam, including: a) the expansion of the current toward the dam; b) the runup against the face of the dam; c) the formation of an upstream-migrating bore as the current reflects off the dam; and d) the establishment of an internal hydraulic jump. Next, a series of sustained turbidity current events entering a reservoir are simulated to capture the loss of reservoir storage capacity in time due to continuous growth of the bottomset deposit and its interaction with the fluvial delta. In the future, the model will be expanded into a valuable tool for evaluating sediment routing, flushing and other operational procedures in reservoirs that can be used as effective climate change mitigation strategies.</font></span></p>
<p><font face="arial, helvetica, sans-serif"><b>HOST:</b> Dr. Jose Castillo</font></p><p><font face="arial, helvetica, sans-serif">For future events, please visit our website at:</font></p><p><a href="http://www.csrc.sdsu.edu/colloquium.html" target="_blank"><font face="arial, helvetica, sans-serif">http://www.csrc.sdsu.edu/colloquium.html</font></a></p>
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<p>Jose E. Castillo Ph.D.</p><p>Director / Professor </p>
<p>Computational Science Research Center</p>
<p>5500 Campanile Dr</p>
<p>San Diego State University</p>
<p>San Diego CA 92182-1245</p>
<p>619 5947205/3430, Fax <a href="tel:619-594-2459" value="+16195942459" target="_blank">619-594-2459</a></p><p> <a href="http://www.csrc.sdsu.edu/mimetic-book/" target="_blank">http://www.csrc.sdsu.edu/mimetic-book/</a></p>
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