Difference between revisions of "Team:Warwick/Modeling"
Line 28: | Line 28: | ||
<br><b>Law of Mass Action</b> | <br><b>Law of Mass Action</b> | ||
− | + | <br>When modelling chemical reactions, we used the law of mass action which explains and predicts behaviours of solutions in dynamic equilibrium. The basis for this law stems from the research conducted by Cato M. Guldberg and Peter Waage in the mid 18 hundreds. Guldberg and Waage recognized that chemical equilibrium is a dynamic process in which rates of reaction for the forward and backward reactions must be equal at chemical equilibrium. In order to find the equilibrium values for the chemicals involved, the differential equation governing the process must be found. | |
<br><br>We have found said differential equation and then analytically solved it. After substituting in empirical data from the experiments, it is impossible to solve the equations to find the binding and unbinding constants (association and disassociation constants). We then used a computational method to find these constants. These results tell the biologists which zinc fingers have the best binding ability. | <br><br>We have found said differential equation and then analytically solved it. After substituting in empirical data from the experiments, it is impossible to solve the equations to find the binding and unbinding constants (association and disassociation constants). We then used a computational method to find these constants. These results tell the biologists which zinc fingers have the best binding ability. | ||
<br><br>Another piece of code then uses these new found values to find out how much reactant to use, the related expenses, and how long the reaction will take. | <br><br>Another piece of code then uses these new found values to find out how much reactant to use, the related expenses, and how long the reaction will take. |
Revision as of 17:15, 16 September 2015