Fix typos

projects/refmap/index.md

@@ -67,7 +67,7 @@ Software: [GenSDF-GitHub Repository](https://github.com/AkshayPatil1994/GenSDF)
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-One of the important aspects of simulating scale-resolving turbulent flows is the need to reduce the spin-up time when using periodic pressure driven channel flows. To that end, we developed a rather simple computational method that generates the initial conditions for pressure-driven channel flows that speeds up the convergence to a statistically stationary flow state by a factor of 5-10 when compared with exisiting community practices. Our method is domain size agnostic and gives a relatively more consistent transition to a turbulent state when compared with other alternatives. This reduction in the spin-up time directly reduces the computational cost and environmental footprint for increasing flow Reynolds numbers. 
+One of the important aspects of simulating scale-resolving turbulent flows is the need to reduce the spin-up time when using periodic pressure driven channel flows. To that end, we developed a rather simple computational method that generates the initial conditions for pressure-driven channel flows that speeds up the convergence to a statistically stationary flow state by a factor of 5-10 when compared with existing community practices. Our method is domain size agnostic and gives a relatively more consistent transition to a turbulent state when compared with other alternatives. This reduction in the spin-up time directly reduces the computational cost and environmental footprint for increasing flow Reynolds numbers. 
 
 Pre-print: [Fake it Till You Make it: Synthetic Turbulence to Achieve Swift Converged Turbulence Statistics in a Pressure-Driven Channel Flow](https://papers.ssrn.com/sol3/papers.cfm?abstract_id=5101082)  
 Software: [GenIC](https://github.com/AkshayPatil1994/Synthetic-Eddy-Method-KCX2013)

projects/turbocor/index.md

@@ -16,7 +16,7 @@ permalink: /projects/turbocor/
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 ## Summary
 
-TurboCor is an indepdent project mainly supported by NWO-Snellius computing grant that aims to better understand the hydrodynamics within morphologically complex coral reef boundary layers. The central idea is to apply scale-resolving computational methods to study the effect of simple and complex coral reef hydrodynamics at a scale never studied before.
+TurboCor is an independent project mainly supported by NWO-Snellius computing grant that aims to better understand the hydrodynamics within morphologically complex coral reef boundary layers. The central idea is to apply scale-resolving computational methods to study the effect of simple and complex coral reef hydrodynamics at a scale never studied before.
 
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 ## Work in progress