Chapter 17

1. Chapter 17 Equilibrium

2. We know reactions take place. • We even know how they take place. • But, why are some slow, some fast? • Why do we have refrigerators? How can we prevent rust?

3. 17.1 How chemical reactions occur • Chemicals have to collide with each other to react. They must touch each other • They must touch each other hard enough to react. Called collision model

4. 17.1 • This spells it all out: if we can keep them from colliding, slower reactions • Get them to collide more often, speedier reactions

5. 17.2 Conditions that affect reaction rates • What Conditions will affect reaction rates? • If we can increase the Concentration of the reactants the reaction should go faster • There is a better chance that collision will occur • Ex. put more O2in a fire andwhoosh!

6. 17.2 Conditions that affect reaction rates • Temperature also increases the chance of collision • Moving faster means better chance of smacking into the other reactant • opposite is reason for refrigeration!

7. 17.2 Conditions that affect reaction rates • But Temperature plays another role • Merely colliding does not mean a reaction will occur • The reactants must hit with the right amount of Energy or they bounce away • The amount of Energy required for a collision to be a good one is called activation energy (Ea)

8. 17.2 Conditions that affect reaction rates • Having Ea will make sure the old bonds are broken so that atom exchange can take place

13. 17.2 Conditions that affect reaction rates • Particle size will affect reaction rate • Particles can only collide at the surface. • Smaller particle size, bigger surface area thus faster reaction • Smallest possible particle size is ions or molecules • That’s why dissolving speeds up reactions. Getting two solids to react is very slow

14. 17.2 Conditions that affect reaction rates • Catalyst • This is a substance that speeds up a reaction without being consumed • In your body the catalysts are called enzymes • It speeds up a reaction by giving the reaction a new path • The new path has a lower activation energy thus goes faster. • An inhibitor is something that blocks the catalyst

15. 17.2 • The catalyst lowers the Ea so more molecules can go over the hill • This appears to our eyes as a speed up in the reaction

16. 17.3 Heterogeneous Reactions • So far we have considered reactions that take place in only one phase • 2 aqueous solutions mixed together • 2 gases mixed together • Those are homogeneous reactions • But a heterogeneous reaction would involve two different phases • e.g., Zn (solid) tossed into HCl (aqueous)

17. 17.3 • These reactions depend on surface area • e.g. a block of Zn reacts a lot slower than Zn dust

18. 17.3 • The reason some grain silos in the Midwest blow up each year

19. a summary

20. 17.4 The Equilibrium Condition • So far we have assumed that reactions proceed until completion – until one of the reactants “runs out”. • Some reactions will stop before completion an equilibrium has been achieved • Equilibrium means balance. For chemistry: the exact balancing of two processes, one of which is the opposite of the other. • Remember dynamic equilibrium & vapor pressure?

22. 17.4 The Equilibrium Condition • Example NO2(g) + NO2(g) N2O4(g) • The brown gas NO2 becomes colorless N2O4 in a flask, but the flask doesn’t become colorless. • Equilibrium was achieved. The concentration of all reactants & products remain the same. • ie the reaction is going forward & backward at the same time. R->P and P->R

23. 17.4 The Equilibrium Condition • When reactants are first put together the forward reaction occurs. • Since there are no products the reverse reaction does not occur. • As the forward reaction proceeds the reactants are used up and the reaction slows. • The products build up and the reverse reaction speeds up.

24. 17.5 Chemical Equilibrium • Eventually you reach a point where the reverse reaction is going as fast as the forward reaction. • This is dynamic equilibrium • The rate of the forward reaction is equal to the rate of the reverse reaction. • The concentrations of the reactant and products stay the same, but the reactions are still running.

25. 17.5 Chemical Equilibrium • Equilibrium position- how much product and reactant there are at equilibrium. • Shown with the double arrow Reactants are favored. Products are favored. Catalysts speed up both forward and reverse reactions so don’t effect equilibrium position.

26. 17.6 The Equilibrium Constant • Science is based on results of experiments. • The equilibrium between reactants and products is described by an equilibrium constant. • For the balanced reaction: aA + bB  cC + dDThe equilibrium constant, Keq is defined as: [C]c [D]d products Keq = --------- [A]a [B]b reactants • where the [ ] brackets indicate the concentration of the chemical species in mol/L. K is the equilibrium constant.

27. 17.6 The Equilibrium Constant • Rules for Writing Keq Expressions • Products are always in the numerator. • Reactants are always in the denominator. • Express gas concentrations as partial pressure, P, and dissolved species in molar concentration, []. • The partial pressures or concentrations are raised to the power of the stoichiometric coefficient for the balanced reaction. • Leave out pure solids or liquids and any solvent.

28. 17.6 The Equilibrium Constant • Example: Zn (s) + 2 H+(aq) Zn2+(aq) + H2 (g) PH2 [Zn2+] Keq = ----------- [H+]2 where PH2 is the partial pressure of H2, [Zn2+] and [H+] are the molar concentrations of Zn2+ and H+, respectively, and Zn (s) is left out of the Keq expression because it is a pure solid.

29. 17.6 The Equilibrium Constant Example • What is the equilibrium expression for the following reaction? H2O(l) H+(aq) + OH-(aq) [H+] [OH-] products Keq = ------------- [H2O] reactants

30. 17.6 The Equilibrium Constant Example • What is the equilibrium expression for the following reaction? 4NH3(g) + 7O2(g) 4NO2(g) + 6H2O(g) [NO2]4 [H2O]6 Keq = ------------------ [NH3]4 [O2]7

31. 17.6 The Equilibrium Constant Example • Calculate the value of Keq for the following reaction N2(g) + 3H2(g) 2NH3(g) if [NH3 (g)] = 0.34M, [H2(g) ] = 2.1 x 10-3M and [N2(g)] = 4.9 x 10-4M [NH3]2[0.34]2 Keq = ------------------  Keq = ------------------------ [N2][H2]3 [4.9 x 10-4][2.1 x 10-3]3 ANSWER: Keq = 2.5 x 1010

32. 17.8 Le Chatelier’s Principle • Le Chatelier's Principle: When a system at equilibrium is disturbed, the equilibrium conditions shift to counteract the disturbance. • Example: N2O4 (g) 2 NO2 (g)    K = 11 (at 25oC) • Sample equilibrium conditions: PN2O4 = 0.027 atm, PNO2 = 0.546 atm in a 4.0 L container at 25oC. • What would disturb this equilibrium? • Changing pressure. • Changing temperature. • Changing the amounts of the reactants or products in the container.

33. 17.8 Le Chatelier’s Principle What can the Keq tell us? When a Keq is calculated • A Keq value greater than 1 means that products are favored over reactants; Keq > 1 • A Keq value less than 1 means that reactants are favored over products; Keq < 1

34. 17.8 Le Chatelier’s Principle Changing Pressure • Example: Decrease the volume of the container in the above example from 4.0 L to 1.0 L (Remember PV = nRT. P and V are inversely proportional!) • New partial pressures: PNO2= 0.546 atm x 4 = 2.18atmPN2O4 = 0.027 atm x 4 = 0.108 atm • In which direction will the reaction proceed to reestablish equilibrium?Calculate the reaction the Keq for the new conditions • Keq= (2.18 atm)2 ÷ 0.108 atm = 44 atmKeq > 1 so the reaction will proceed in the reverse direction favoring the products.

35. How do we find the new equilibrium partial pressures? • Start with the new initial conditions: PNO2 = 2.18 atmand PN2O4 = 0.108 atm • Q tells us the reaction will shift in the reverse direction, N2O4 (g) 2 NO2 (g). The problem is set up in the following: • N2O4NO2Po0.108 atm2.18 atmP+0.5x atm-x atmPeq(0.108+0.5x) atm(2.18-x) atmK = 11 = (2.18-x)2 / (0.108+0.5x) • Find x, then find PNO2 and PN2O4