Editing revision 27 of ChemicalEquilibrium
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<b>Here are the basic procedures for solving equilibrium problems:</b> (from Zumdahl textbook) <li>Write the balanced equation for the reaction. <li>Write the equilibrium expression using the law of mass action. <li>List the initial concentrations. <li>Calculate "Q," and determine the direction of the shift to equilibrium. <li>Define the change needed to reach equilibrium, and define the equilibrium concentrations by applying the change to the initial concentrations. <li>Substitute the equilibrium concentrations ionto the equilibrium expression, and solve for the unknown. <li>Check your calculated equilibrium concentrations by making sure they give the correct value of "K." <b>Examples:</b> <b>1.</b> Assume that the reaction for the formation of gaseous hydrogen iodide from hydrogen and iodine has an equilibrium constant of 2.3 x 10<sup>2</sup>. In an experiment, 4.0 mol H<sub>2</sub> and 2.0 mol of I<sub>2</sub> were added to a 2.0 L flask. Find the equilibrium concentrations of all species involved in this reaction. The balanced equation for the reaction is: H<sub>2(g)</sub> + I<sub>2(g)</sub> <--> 2HI<sub>(g)</sub> The equilibrium expression is: K = 2.0 x 10<sup>2</sup> = [HI]<sup>2</sup> / [H<sub>2</sub>][I<sub>2</sub>] First, you must calculate the initial concentrations. [HI]<sub>0</sub> = [H<sub>2</sub>]<sub>0</sub> = 4.0 mol / 2.0 L [I<sub>2</sub>]<sub>0</sub> = 2.0 mol / 2.0 L = 1.0 M Next, find the value of Q (initial conditions): Q = [HI]<sup>2</sup><sub>0</sub> / [H<sub>2</sub>]<sub>0</sub>[I<sub>2</sub>]<sub>0</sub> = (2.0 M)<sup>2</sup> / (2.0 M)(2.0 M) = 1.00 <i>Since Q is less than K, the system will shift to the <b>right</b> (towards the products). </i> Now, determine what chang ein concentrations is necessary in order for this shift to take place. We do not yet know the amount we will need, so let that amount equal "x." In this problem, let "x" equal the number of moles per liter of H<sub>2</sub> consumed to reach equilibrium. Take a look at the reaction. H<sub>2(g)</sub> + I<sub>2(g)</sub> <--> 2HI<sub>(g)</sub> The stoichiometry of this reaction indicates that x mol/L I<sub>2</sub> will be consumed and 2x mol/L HI will be produced. To help you see this problem more clearly, set up a chart that will allow you to express equilibrium concentrations in terms of "x." Initial Concentration: [H<sub>2</sub>]<sub>0</sub> = 2.0 M [I<sub>2</sub>]<sub>0</sub> = 1.0 M [HI]<sub>0</sub> = 0 M Change: [H<sub>2</sub>] = -x [I<sub>2</sub>] = -x [HI] = +2x Equilibrium Concentration: [H<sub>2</sub>] = 2.0 M - x [I<sub>2</sub>] = 1.0 M - x [HI] = 0 + 2x Plug the equilibrium concnetrations into the equlibrium expression to give you: K = 2.3 x 10<sup>2</sup> = [HI]<sup>2</sup> / [H<sub>2</sub>][I<sub>2</sub>] = (2x)<sup>2</sup> / (2.0 M - x)(1.0 M - x)
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