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                 <b>Instructions:</b> Click and drag to apply a force to the fluid.  Over time, the colored material in the fluid will dissipate:
                 <img style="width:100%" src="img2.png"/>
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-                To learn more about the math involved, check out the following sources:<br/>
+                To learn more about the math involved, see the following sources:<br/>
                 <a href="https://pdfs.semanticscholar.org/84b8/c7b7eecf90ebd9d54a51544ca0f8ff93c137.pdf" target="_blank">Real-time ink simulation using a grid-particle method</a> - mixing Eulerian and Lagrangian techniques for fluids.<br/>
                 <a href="http://http.developer.nvidia.com/GPUGems/gpugems_ch38.html" target="_blank">Fast Fluid Dynamics Simulation on the GPU</a> - a very well written tutorial about programming the Navier-Stokes equations on a GPU.
                 Though not WebGL specific, it was still very useful.<br/>
                 <a href="http://jamie-wong.com/2016/08/05/webgl-fluid-simulation/" target="_blank">Fluid Simulation (with WebGL demo)</a> - this article has some nice, interactive graphics that helped me debug my code.<br/>
                 <a href="http://www.dgp.toronto.edu/people/stam/reality/Research/pdf/ns.pdf" target="_blank">Stable Fluids</a> - a paper about stable numerical methods for evaluating Navier-Stokes on a discrete grid.<br/>
                 <br/>
-                By <a href="http://www.amandaghassaei.com/" target="_blank">Amanda Ghassaei</a>, code on <a href="https://github.com/amandaghassaei/FluidSimulation" target="_blank">Github</a>.
+                By <a href="http://www.amandaghassaei.com/" target="_blank">Amanda Ghassaei.
                 <br/><br/>
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