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Predicting if a Reaction is in Equilibrium Trial Keq Lesson 9.

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Presentation on theme: "Predicting if a Reaction is in Equilibrium Trial Keq Lesson 9."— Presentation transcript:

1 Predicting if a Reaction is in Equilibrium Trial Keq Lesson 9

2 The Keq is a constant- a number that does not change. Changing the volume, pressure, or any concentration, does not change the Keq. Only temperature changes the Keq If the [Reactant] is increased the reaction will shift

3 The Keq is a constant- a number that does not change. Changing the volume, pressure, or any concentration, does not change the Keq. Only temperature changes the Keq If the [Reactant] is increased the reaction will shift right The Keq will

4 The Keq is a constant- a number that does not change. Changing the volume, pressure, or any concentration, does not change the Keq. Only temperature changes the Keq If the [Reactant] is increased the reaction will shift right The Keq will remain constant If the temperature of an endothermic reaction is increased the reaction will

5 The Keq is a constant- a number that does not change. Changing the volume, pressure, or any concentration, does not change the Keq. Only temperature changes the Keq If the [Reactant] is increased the reaction will shift right The Keq will remain constant If the temperature of an endothermic reaction is increased the reaction will shift right The Keq will

6 The Keq is a constant- a number that does not change. Changing the volume, pressure, or any concentration, does not change the Keq. Only temperature changes the Keq If the [Reactant] is increased the reaction will shift right The Keq will remain constant If the temperature of an endothermic reaction is increased the reaction will shift right The Keq will increase

7 1.If 6.00 moles CO 2, and 6.00 moles H 2 are put in a 2.00 L container at 670 o C, calculate all equilibrium concentrations. CO (g) + H 2 O (g) ⇄ CO 2(g) + H 2(g) Keq = 9.0 Initial concentrations means ICE! Because we are starting with products it goes left Add on left and subtract on right I003.00 M3.00 M C+x+x-x-x Exx3.00 - x3.00 - x Keq=[CO 2 ][H 2 ]=9.0 [CO][H 2 O]

8 Keq=(3 - x) 2 =9 x 2 Square root both sides 3 - x =3 x1 Cross multiply 3x=3 - x 4x=3 [CO]= [H 2 O] =x=0.75 M [CO 2 ]= [H 2 ] = 3.00 - 0.75 = 2.25 M

9 Ktrial How can you tell if a system is in equilibrium or not? Calculate a trial Keq. Put the concentrations into the equilibrium expression and evaluate.

10 Ktrial How can you tell if a system is in equilibrium or not? Calculate a trial Keq. Put the concentrations into the equilibrium expression and evaluate. If Ktrial = KeqEquilibrium Keq Kt

11 Ktrial How can you tell if a system is in equilibrium or not? Calculate a trial Keq. Put the concentrations into the equilibrium expression and evaluate. If Ktrial = KeqEquilibrium If Ktrial < KeqNot at Equilibrium Keq Kt

12 Ktrial How can you tell if a system is in equilibrium or not? Calculate a trial Keq. Put the concentrations into the equilibrium expression and evaluate. If Ktrial = KeqEquilibrium If Ktrial < KeqNot at Equilibrium Shifts Right Keq Kt

13 Ktrial How can you tell if a system is in equilibrium or not? Calculate a trial Keq. Put the concentrations into the equilibrium expression and evaluate. If Ktrial = KeqEquilibrium If Ktrial < KeqNot at Equilibrium Shifts Right If Ktrial > Keq KeqKt

14 Ktrial How can you tell if a system is in equilibrium or not? Calculate a trial Keq. Put the concentrations into the equilibrium expression and evaluate. If Ktrial = KeqEquilibrium If Ktrial < KeqNot at Equilibrium Shifts Right If Ktrial > KeqNot at Equilibrium Shifts Left KeqKt

15 The following amounts of gases are placed into a 2.0 L container. Determine if each system is at equilibrium or not. If not, determine the direction that the equilibrium will shift in order to get to equilibrium. 2NH 3(g) ⇄ N 2(g) + 3H 2(g) Keq = 10 1.2.0 moles NH 3 2.0 moles N 2 2.0 mole H 2 Get concentrations. 1.0 M1.0 M1.0 M Calculate Kt Kt=[N 2 ][H 2 ] 3 =(1)(1) 3 = 1 [NH 3 ] 2 (1) 2 Not in equilibriumKt < Keq Shifts right!

16 The following amounts of gases are placed into a 2.0 L container. Determine if each system is at equilibrium or not. If not, determine the direction that the equilibrium will shift in order to get to equilibrium. 2NH 3(g) ⇄ N 2(g) + 3H 2(g) Keq = 10 2.2.0 moles NH 3 4.0 moles N 2 4.0 mole H 2 Get concentrations. 1.0 M2.0 M2.0 M Calculate Kt Kt=[N 2 ][H 2 ] 3 =(2)(2) 3 = 16 [NH 3 ] 2 (1) 2 Not in equilibriumKt > Keq Shifts left!

17 The following amounts of gases are placed into a 2.0 L container. Determine if each system is at equilibrium or not. If not, determine the direction that the equilibrium will shift in order to get to equilibrium. 2NH 3(g) ⇄ N 2(g) + 3H 2(g) Keq = 10 3.2.0 moles NH 3 2.5 moles N 2 4.0 mole H 2 Get concentrations. 1.0 M1.25 M2.0 M Calculate Kt Kt=[N 2 ][H 2 ] 3 =(1.25)(2) 3 = 10 [NH 3 ] 2 (1) 2 In equilibriumKt = Keq

18 4.If 4.00 moles of CO, 4.00 moles H 2 O, 6.00 moles CO 2, and 6.00 moles H 2 are placed in a 2.00 L container at 670 o C, Keq = 1.0 CO (g) + H 2 O (g) ⇄ CO 2(g) + H 2(g) Is the system at equilibrium? If not, how will it shift in order to get there? Calculate all equilibrium concentrations. Get Molarities 2.00 M2.00 M3.00 M3.00 M Calculate a Kt Kt=(3)(3)=2.25 (2)(2) Not in equilibriumShifts left!

19 Do an ICE chart CO (g) + H 2 O (g) ⇄ CO 2(g) + H 2(g) I 2.00 M2.00 M3.00 M3.00 M C+x+x-x-x E2.00 + x2.00 + x3.00 - x3.00 - x Keq=(3 - x) 2 =1.0 (2 + x) 2 Square root 3 - x =1.0 2 + x 3 - x = 2 + x 1=2x x = 0.50 M [CO 2 ]=[H 2 ]=3.00 - 0.50 = 2.50 M [CO]=[H 2 O]=2.00 + 0.50 = 2.50 M

20 Size of the Keq

21 Big Keq Keq= Keq=10 products reactants

22 Little Keq- Keq= Keq=0.1 Note that the keq cannot be a negative number! products reactants

23 Keqabout 1 Keq= Keq=1 products reactants

24 Which reaction favours the products the most? Keq = 2.6 x 10 6 Keq = 3.5 x 10 2 Which reaction favours the reactants the most? Keq = 2.6 x 10 -6 Keq = 3.5 x 10 -7

25 Which reaction favours the products the most? Keq = 2.6 x 10 6 Keq = 3.5 x 10 2 Which reaction favours the reactants the most? Keq = 2.6 x 10 -6 Keq = 3.5 x 10 -7

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