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Le Châtelier’s principle

Le Châtelier’s principle. Kc =. The significance of Kc values. If Kc is small (0.001 or lower), [products] must be small, thus forward reaction is weak If Kc is large (1000 or more), [products] must be large, thus forward reaction is strong. Read 14.6 (560 - 561) do PE5.

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Le Châtelier’s principle

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  1. Le Châtelier’s principle

  2. Kc = The significance of Kc values If Kc is small (0.001 or lower), [products] must be small, thus forward reaction is weak If Kc is large (1000 or more), [products] must be large, thus forward reaction is strong • Read 14.6 (560 - 561) do PE5 If Kc is about 1, then reactants and products are about equal but not exactly since they may be raise to different exponents Reactants  Products [Products] [Reactants]

  3. 30 Volume 20 # of transfers 15 20 Altering the straw lab • The volumes stopped changing at 30, 20 mL • Recall the lab with large and small straws Q - Predict what will happen when: 5 ml is added to GC2 at 15 transfers, and then 10 ml is removed from GC1 at 20 transfers

  4. Stresses to equilibria • Changes in reactant or product concentrations is one type of “stress” on an equilibrium • Other stresses are temperature, and pressure. • The response of equilibria to these stresses is explained by Le Chatelier’s principle: If an equilibrium in a system is upset, the system will tend to react in a direction that will reestablish equilibrium • Thus we have: 1) Equilibrium, 2) Disturbance of equilibrium, 3) Shift to restore equilibrium • Le Chatelier’s principle predicts how an equilibrium will shift (but does not explain why) • Movie (10 minutes at 1:10) - Le Châtelier

  5. Summary of Le Chatelier’s principle • Amounts of products and reactants: equilibrium shifts to compensate • N2  H2 E.g. N2 + 3H2 2 NH3 + 92 kJ N2 + 3H2 2NH3 + 92 kJ shift right N2 + 3H2 2NH3 + 92 kJ N2 + 3H2 2NH3 + 92 kJ N2 + 3H2 2NH3 + 92 kJ shift left N2 + 3H2 2NH3 + 92 kJ N2 + 3H2 2NH3 + 92 kJ Temperature: equilibrium shifts to compensate:  Heat N2 + 3H2 2NH3 + 92 kJ shift left N2 + 3H2 2NH3 + 92 kJ N2 + 3H2 2NH3 + 92 kJ Pressure (due to decreased volume): increase in pressure favors side with fewer molecules Catalysts: does not influence reaction

  6. Sample values Kc = [0.150] , 300 = [0.0222][0.0225] • The response to changes in an equilibrium can be explained via the equilibrium law • Consider C2H4(g) + H2O(g)  C2H5OH(g) Le Châtelier and the equilibrium law [C2H5OH] [C2H4][H2O] • What happens if 1 mol C2H5OH is added? • Now mass action expression = 2300 • Recall Kc does not change (for a given temp) • To reestablish equilibrium we must reduce 2300 to 300 ( top,  bottom = shift left) • The equilibrium law explains Le chatelier’s principle (compensating for stresses)

  7. Kc = [0.150] , 300 = [0.0222][0.0225] • Pressure will increase if: 1)volume decreases, 2) a (unrelated/inert) gas is added • Only the first will cause a shift in equilibrium… C2H4(g) + H2O(g)  C2H5OH(g) Pressure and equilibrium [C2H5OH] [C2H4][H2O] • If volume is reduced, for example, by half, we will have [0.300]/[0.0444][0.0450] = 150 • To get back to 300, we must have a shift to the right (fewest number of particles) • However, if pressure is increased by adding an unrelated gas [ ]s do not change

  8. Catalysts, Le Châtelier questions • The last factor to consider is the addition of a catalyst: this does not affect an equilibrium • A catalyst speeds both forward and reverse reactions (by lowering the activation energy) • It allows us to get to equilibrium faster, but it does not alter equilibrium concentrations Q- predict the colour of the “NO2 tubes” if they are heated and/or cooled (the reaction is endothermic when written as): N2O4(colourless)  2NO2 (brown) Q- 14.24-.27, .29 (p. 589), refer to 14.7 (561-5) Q-for fig 14.4 (562) what happens if N2 is added

  9. N2O4(colourless) + heat  2NO2 (brown) Increasing temp causes shift to right (brown) Cooling causes shift to left (colourless) 14.24 -When an equilibrium is disturbed, the system shifts to re-establish equilibrium 14.25 - shift to a) right(r), b) left(l), c) r, d) l, e) r 14.26 -a) -r, b) -l, c) -r), d) no change, e) -l 14.27 - e) in both (only a change in temperature will cause a change in Kc). 14.29 - a) and d) N2 will rise sharply then gradually decrease as more NH3 is (gradually) produced. H2 will decrease. Final [ ]s of N2 and NH3 will be higher than before adding N2; H2 will be lower. Answers For more lessons, visit www.chalkbored.com

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