18-1 CHEM 102, Spring 2012 LA TECH CTH 328 10:00-11:15 am Instructor: Dr. Upali Siriwardane Office: CTH 311 Phone 257-4941 Office.

18-1 CHEM 102, Spring 2012 LA TECH CTH 328 10:00-11:15 am Instructor: Dr. Upali Siriwardane e-mail: upali@latech.edu Office: CTH 311 Phone 257-4941 Office Hours: M,W 8:00-9:00 & 11:00-12:00 am; Tu, Th, F 8:00 - 10:00am.. Exams: 10:00-11:15 am, CTH 328. September 27, 2012 (Test 1): Chapter 13 October 18, 2012 (Test 2): Chapter 14 &15 November 13, 2012 (Test 3): Chapter 16 &18 Optional Comprehensive Final Exam: November 15, 2012 : Chapters 13, 14, 15, 16, 17, and 18 Chemistry 102(001) Fall 2012

18-2 CHEM 102, Spring 2012 LA TECH Review of Chapter 6. Energy and Chemical Reactions 6.1 The Nature of Energy 6.2 Conservation of Energy 6.3 Heat Capacity 6.4 Energy and Enthalpy 6.5 Thermochemical Equations 6.6 Enthalpy change for chemical Rections 6.7 Where does the Energy come from? 6.8 Measuring Enthalpy Changes: Calorimetry 6.9 Hess's Law 6.10 Standard Enthalpy of Formation 6.11 Chemical Fuels for Home and Industry 6.12 Food Fuels for Our Bodies

18-3 CHEM 102, Spring 2012 LA TECH Chapter 18. Thermodynamics: Directionality of Chemical Reactions 18.1Reactant-Favored and Product-Favored Processes 18.2Probability and Chemical Reactions 18.3Measuring Dispersal or Disorder: Entropy 18.4Calculating Entropy Changes 18.5Entropy and the Second Law of Thermodynamics 18.6Gibbs Free Energy 18.7Gibbs Free Energy Changes and Equilibrium Constants Constants 18.8Gibbs Free Energy, Maximum Work, and Energy Resources 18.9Gibbs Free Energy and Biological Systems 18.10Conservation of Gibbs Free Energy 18.11Thermodynamic and Kinetic Stability

18-4 CHEM 102, Spring 2012 LA TECH What is Hess's Law of Summation of Heat? To heat of reaction for new reactions. Two methods? 1st method: new  H is calculated by adding  Hs of other reactions. 2nd method: Where  H f (  H of formation) of reactants and products are used to calculate  H of a reaction.

18-5 CHEM 102, Spring 2012 LA TECH Method 1: Calculate  H  H for the reaction: SO 2 (g) + 1/2 O 2 (g) + H 2 O(g) ----> H 2 SO 4 (l)  H = ? Other reactions: SO 2 (g) ------> S(s) + O 2 (g) ;  H = 297kJ H 2 SO 4 (l)------> H 2 (g) + S(s) + 2O 2 (g);  H = 814 kJ H 2 (g) +1/2O 2 (g) -----> H 2 O(g);  H = -242 kJ Other reactions: SO 2 (g) ------> S(s) + O 2 (g) ;  H = 297kJ H 2 SO 4 (l)------> H 2 (g) + S(s) + 2O 2 (g);  H = 814 kJ H 2 (g) +1/2O 2 (g) -----> H 2 O(g);  H = -242 kJ

18-6 CHEM 102, Spring 2012 LA TECH SO 2 (g) ------> S(s) + O 2 (g);  H 1 = 297 kJ - 1 H 2 (g) + S(s) + 2O 2 (g) ------> H 2 SO 4 (l);  H 2 = -814 kJ - 2 H 2 O(g) ----->H 2 (g) + 1/2 O 2 (g) ;  H 3 = +242 kJ - 3 ______________________________________ SO 2 (g) + 1/2 O 2 (g) + H 2 O(g) -----> H 2 SO 4 (l);  H = ? SO 2 (g) + 1/2 O 2 (g) + H 2 O(g) -----> H 2 SO 4 (l);  H = ?   H =  H 1 +  H 2 +  H 3   H = +297 - 814 + 242  H = -275 kJ Calculate  H for the reaction

18-7 CHEM 102, Spring 2012 LA TECH 1) Calculate entropy change for the reaction: 2 C(s) + 1/2 O 2 (g) + 3 H 2 (g)--> C 2 H 6 O(l); ∆H = ? (ANS -277.1 kJ/mol) Given the following thermochemical equations: C 2 H 6 O(l) + 3 O 2 (g) ---> 2 CO 2 (g) + 3 H 2 O(l); ∆H = - 1366.9 kJ/mol 1/2 O 2 (g) + H2(g) ----> H 2 O(l);∆H = -285.8 kJ/mol C(s) + O 2 (g) ----> CO 2 (g);∆H = -393.3 kJ/mol

18-8 CHEM 102, Spring 2012 LA TECH Calculate Heat (Enthalpy) of Combustion: 2nd method C 7 H 16 (l) + 11 O 2 (g) -----> 7 CO 2 (g) + 8 H 2 O(l) ;  H o = ? C 7 H 16 (l) + 11 O 2 (g) -----> 7 CO 2 (g) + 8 H 2 O(l) ;  H o = ?  H f (C 7 H 16 ) = -198.8 kJ/mol  H f (CO 2 ) = -393.5 kJ/mol  H f (H 2 O) = -285.9 kJ/mol  H f O 2 (g) = 0 (zero) What method?  H o =  n   H f o products –  n   H f o reactants n = stoichiometric coefficients 2 nd method

18-9 CHEM 102, Spring 2012 LA TECH  H = [  n (  H o f ) Products] - [  n (  H o f ) reactants]  H = [ 7(- 393.5 + 8 (- 285.9)] - [-198.8 + 11 (0)] = [-2754.5 - 2287.2] - [-198.8] = [-2754.5 - 2287.2] - [-198.8] = -5041.7 + 198.8 = -5041.7 + 198.8 = -4842.9 kJ = -4843 kJ = -4842.9 kJ = -4843 kJ Calculate  H for the reaction

18-10 CHEM 102, Spring 2012 LA TECH Why is  H o f  H o f of elements is zero?  H o f, Heat formations are for compounds Note:  H o f of elements is zero

18-11 CHEM 102, Spring 2012 LA TECH 2) Calculate entropy change given the ∆Hf o [SO 2 (g)] = -297 kJ/mole and ∆Hf o [SO 3 (g)] = -396 kJ/mole 2SO 2 (g) + O 2 (g) -----> 2 SO 3 (g); ∆H= ? ANS -198 kJ/mole)

18-12 CHEM 102, Spring 2012 LA TECH What is relation of  H of a reaction to covalent bond energy?  H =  bonds broken  -   bonds formed  How do you calculate bond energy from  H? How do you calculate  H from bond energy?

18-13 CHEM 102, Spring 2012 LA TECH

18-14 CHEM 102, Spring 2012 LA TECH 3) Use the table of bond energies to find the ∆H o for the reaction: H 2 (g) + Br 2 (g)  2 HBr(g); H-H = 436 kJ, Br-Br= 193 kJ, H-Br = 366 kJ

18-15 CHEM 102, Spring 2012 LA TECH Example. Calculate the  S o rxn at 25 o C for the following reaction. CH4 (g) + 2O2 (g) CO2 (g) + 2H2O (g) Substance S (J/K.mol) Substance S o (J/K.mol) CH 4 (g) 186.2 O 2 (g) 205.03 CO 2 (g) 213.64 H 2 O (g) 188.72 Calculation of standard entropy changes

18-16 CHEM 102, Spring 2012 LA TECH Calculate the  S for the following reactions using  S o =   S o (products) -   S o (reactants) a) 2SO 2 (g) + O 2 (g) ------> 2SO 3 (g)  S o [SO 2 (g)] = 248 J/K mole ;  S o [O 2 (g)] = 205 J/K mole;  S o [SO 3 (g)] = 257 J/K mole b) 2NH 3 (g) + 3N 2 O (g) --------> 4N 2 (g) + 3 H 2 O (l)  S o [ NH 3 (g)] = 193 J/K mole ;  S o [N 2 (g)] = 192 J/K mole;  S o [N 2 O(g)] = 220 J/K mole;  S[ H 2 O(l)] = 70 J/K mole

18-17 CHEM 102, Spring 2012 LA TECH a)2SO 2 (g) + O 2 (g------> 2SO 3 (g)  S o [SO 2 (g)] = 248 J/K mole ;  S o [O 2 (g)] = 205 J/K mole;  S o [SO 3 (g)] = 257 J/K mole  S o 496 205 514  S o =   S o (products) -   S o (reactants)  S o = [514] - [496 + 205]  S o = 514 - 701  S o = -187 J/K mole

18-18 CHEM 102, Spring 2012 LA TECH 2 H 2 (g) + O 2 (g)  2 H 2 O(liq) 2 H 2 (g) + O 2 (g)  2 H 2 O(liq)  S o = 2 S o (H 2 O) - [2 S o (H 2 ) + S o (O 2 )]  S o = 2 mol (69.9 J/Kmol) – [2 mol (130.7 J/Kmol) + 1 mol (205.3 J/Kmol)]  S o = -326.9 J/K There is a decrease in S because 3 mol of gas give 2 mol of liquid. Calculating  S for a Reaction Based on Hess’s Law second method: S o =  S o (products) -  S o (reactants)  S o =  S o (products) -  S o (reactants) Based on Hess’s Law second method: S o =  S o (products) -  S o (reactants)  S o =  S o (products) -  S o (reactants)

18-19 CHEM 102, Spring 2012 LA TECH 4) Calculate the ∆S for the following reaction using: a) 2SO 2 (g) + O2 (g) ----> 2SO 3 (g) S o [SO 2 (g)] = 248 J/K mole ; S o [O 2 (g)] = 205 J/K mole; S o [SO 3 (g)] = 257 J/K mole

18-20 CHEM 102, Spring 2012 LA TECH  G The sign of  G indicates whether a reaction will occur spontaneously. +Not spontaneous 0 At equilibrium -Spontaneous  S  G The fact that the effect of  S will vary as a function of temperature is important. This can result in changing the sign of  G. Free energy,  G

18-21 CHEM 102, Spring 2012 LA TECH  G f o Free energy change that results when one mole of a substance if formed from its elements will all substances in their standard states.  G values can then be calculated from:  G o =  np  G f o products –  nr  G f o reactants Standard free energy of formation,  G f o

18-22 CHEM 102, Spring 2012 LA TECH Substance  G f o Substance  G f o C (diamond) 2.832HBr (g) -53.43 CaO (s) -604.04HF (g) -273.22 CaCO3 (s) -1128.84 HI (g) 1.30 C2H2 (g) 209H2O (l) -237.18 C2H4 (g) 86.12H2O (g) -228.59 C2H6 (g) -32.89NaCl (s) -384.04 CH3OH (l) -166.3O (g) 231.75 CH3OH (g) -161.9SO2 (g) -300.19 CO (g) -137.27SO3 (g) -371.08 All have units of kJ/mol and are for 25 o C Standard free energy of formation

18-23 CHEM 102, Spring 2012 LA TECH How do you calculate  G There are two ways to calculate  G for chemical reactions. i)  G =  H - T  S. ii)  G o =   G o f (products) -   G o f (reactants)

18-24 CHEM 102, Spring 2012 LA TECH Calculating  G o rxn Method (a) : From tables of thermodynamic data we find  H o rxn = +25.7 kJ  H o rxn = +25.7 kJ  S o rxn = +108.7 J/K or +0.1087 kJ/K  G o rxn = +25.7 kJ - (298 K)(+0.1087 J/K) = -6.7 kJ = -6.7 kJ Reaction is product-favored in spite of negative  H o rxn. Reaction is “entropy driven” NH 4 NO 3 (s) + heat  NH 4 NO 3 (aq)

18-25 CHEM 102, Spring 2012 LA TECH Calculating  G o rxn Combustion of carbon C(graphite) + O 2 (g) --> CO 2 (g) Method (b) :  G o rxn =  G f o (CO 2 ) - [  G f o (graph) +  G f o (O 2 )]  G o rxn = -394.4 kJ - [ 0 + 0] Note that free energy of formation of an element in its standard state is 0.  G o rxn = -394.4 kJ Reaction is product-favored G o rxn =  G f o (products) -  G f o (reactants)  G o rxn =   G f o (products) -   G f o (reactants)

18-26 CHEM 102, Spring 2012 LA TECH We can calculate  G o values from  Ho and  S o values at a constant temperature and pressure.Example. Determine  G o for the following reaction at 25 o C EquationN 2 (g) + 3H 2 (g) 2NH 3 (g)  H f o, kJ/mol0.00 0.00 -46.11 S o, J/K.mol 191.50 130.68 192.3 Calculation of  G o

18-27 CHEM 102, Spring 2012 LA TECH Predict the spontaneity of the following processes from  H and  S at various temperatures. a)  H = 30 kJ,  S = 6 kJ, T = 300 K b)  H = 15 kJ,  S = -45 kJ,T = 200 K

18-28 CHEM 102, Spring 2012 LA TECH a)  H = 30 kJ  S = 6 kJT = 300 K  G =  H sys -T  S sys or  G =  H - T  S.  H = 30 kJ  S= 6 kJ T = 300 K  G = 30 kJ - (300 x 6 kJ) = 30 -1800 kJ  G = -1770 kJ b)  H = 15 kJ  S = -45 kJT = 200 K  G =  H sys -T  S sys or  G =  H - T  S.  H = 15 kJ  S = -45 kJ T = 200 K  G = 15 kJ -[200 (-45 kJ)] = 15 kJ -(-9000) kJ  G = 15 + 9000 kJ = 9015 kJ

18-29 CHEM 102, Spring 2012 LA TECH 5) Predict the spontaneity of the following processes from ∆H and ∆S at various temperatures. a) ∆H = 30 kJ ∆S = 6 kJT = 300 K b) ∆H = 15 kJ ∆S = -45 kJ T = 200 K

18-30 CHEM 102, Spring 2012 LA TECH 6) Calculate the ∆G o for the following chemical reactions using given ∆H o values, ∆S o calculated above and the equation ∆G = ∆H - T∆S. 2SO 2 (g) + O 2 (g) > 2 SO 3 (g) ; ∆G o = ∆ H o = -198 kJ/mole; ∆S o = -187 J/K mole; T = 298 K ∆ G o system ∆ H o system ∆ S o system T

18-31 CHEM 102, Spring 2012 LA TECH 7) Which of the following condition applies to a particular chemical reaction, the value of ∆H° = 98.8 kJ and ∆S° = 141.5 J/K. This reaction is ∆G system ∆H system ∆ S system T a)Negative always Negative (exothermic) PositiveYes a)Negative at low T Positive at high T Negative (exothermic) Negative ∆ G =-,at low T; ∆ G= +, at high T a)Positive at low T Negative at high T Positive (endothermic) Positive ∆ G = +,at low T; ∆ G= -, at high T a)Positive alwaysPositive (endothermic) Negative ∆ G= +, at any T

18-32 CHEM 102, Spring 2012 LA TECH Effect of Temperature on Reaction Spontaneity

18-33 CHEM 102, Spring 2012 LA TECH  G o =  H o - T  S o

18-34 CHEM 102, Spring 2012 LA TECH 8) At what temperature a particular chemical reaction, with the value of ∆H° = 98.8 kJ and ∆S° = 141.5 J/K becomes a) Equilibrium: b) Spontaneous:

18-35 CHEM 102, Spring 2012 LA TECH How do you calculate  G at different T and P  G =  G o + RT ln Q Q = reaction quotient Q = reaction quotient at equilibrium  G =   =  G o + RT ln K  G o = - RT ln K If you know  G o you could calculate K

18-36 CHEM 102, Spring 2012 LA TECH Concentrations, Free Energy, and the Equilibrium Constant Equilibrium Constant and Free Energy  G =  G o + RT ln Q Q = reaction quotient 0 =  G o + RT ln K eq  G o = - RT ln K eq

18-37 CHEM 102, Spring 2012 LA TECH 9) Calculate the non standard ∆G for the following equilibrium reaction and predict the direction of the change using the equation: ∆G= ∆G o + RT ln Q Given ∆G f o [NH 3 (g)] = -17 kJ/mole N 2 (g) + 3H 2 (g) → 2NH 3 (g); ∆G=? at 300K, P N2 = 300, P NH3 = 75 and P H2 = 300

18-38 CHEM 102, Spring 2012 LA TECH 10) The K a expression for the dissociation of acetic acid in water is based on the following equilibrium at 25°C: HC 2 H 3 O 2 (l) + H 2 O ⇄ H + (aq) + C 2 H 3 O 2 - (aq) What is ∆G° if K a =1.8 x 10 -5 ?

18-39 CHEM 102, Spring 2012 LA TECH Calculate the  G value for the following reactions using:  G o =   G o f (products) -   G o f (reactants) N 2 O 5 (g) + H 2 O(l) ------> 2 HNO 3 (l) ;  G o = ?  G f o [ N 2 O 5 (g) ] = 134 kJ/mole ;  G f o [H 2 O(g)] = -237 kJ/mole;  G f o [ HNO 3 (l) ] = -81 kJ/mole N 2 O 5 (g) + H 2 O(l) ------> 2 HNO 3 (l) ;  G o = ?  G f o 1 x 134 1 x (-237) 2 (-81) 134 -237 -162  G o =  G o f (products) - 3  G o f (reactants)  G o = [-162] - [134 + (-237)]  G o = -162 + 103  G o = -59 kJ/mole The reaction have a negative  G and the reaction is spontaneous or will take place as written.

18-40 CHEM 102, Spring 2012 LA TECH Free Energy and Temperature 2 Fe 2 O 3 (s) + 3 C(s) ---> 4 Fe(s) + 3 CO 2 (g)  H o rxn = +467.9 kJ  S o rxn = +560.3 J/K  G o rxn = +300.8 kJ Reaction is reactant-favored at 298 K At what T does  G o rxn change from (+) to (-)? Set  G o rxn = 0 =  H o rxn - T  S o rxn

18-41 CHEM 102, Spring 2012 LA TECH K eq is related to reaction favorability and so to G o rxn. The larger the (-) value of  G o rxn the larger the value of K.  G o rxn = - RT ln K  G o rxn = - RT ln K where R = 8.31 J/Kmol Thermodynamics and K eq

18-42 CHEM 102, Spring 2012 LA TECH For gases, the equilibrium constant for a reaction can be related to  G o by:  G o = -RT lnK For our earlier example, N 2 (g) + 3H 2 (g) 2NH 3 (g) At 25oC,  Go was -32.91 kJ so K would be: ln K = = ln K = 13.27; K = 5.8 x 10 5  Go -RT -32.91 kJ -(0.008315 kJ.K-1mol-1)(298.2K) Free energy and equilibrium

18-43 CHEM 102, Spring 2012 LA TECH Calculate the  G for the following equilibrium reaction and predict the direction of the change using the equation:  G =  G o + RT ln Q ; [  G f o [ NH 3 (g) ] = -17 kJ/mole N 2 (g) + 3 H 2 (g) 2 NH 3 (g);  G = ? at 300 K, P N2 = 300, P NH3 = 75 and P H2 = 300 N 2 (g) + 3 H 2 (g) 2 NH 3 (g);  G = ?

18-44 CHEM 102, Spring 2012 LA TECH To calculate  G o Using  G o =   G o f (products) -   G o f (reactants)  G f o [ N 2 (g)] = 0 kJ/mole;  G f o [ H 2 (g)] = 0 kJ/mole;  G f o [ NH 3 (g)] = -17 kJ/mole Notice elements have  G f o = 0.00 similar to  H f o N 2 (g) + 3 H 2 (g) 2 NH 3 (g);  G = ?  G f o 002 x (-17) 00-34  G o =   G o f (products) -   G o f (reactants)  G o = [-34] - [0 +0]  G o = -34  G o = -34 kJ/mole

18-45 CHEM 102, Spring 2012 LA TECH To calculate Q Equilibrium expression for the reaction in terms of partial pressure: N 2 (g) + 3 H 2 (g) 2 NH 3 (g) p 2 NH3 K=_________ p N2 p 3 H2 p 2 NH3 Q=_________ ; p N2 p 3 H2 Q is when initial concentration is substituted into the equilibrium expression 75 2 Q=_________ ; p 2 NH3 = 75 2 ; p N2 =300; p 3 H2 =300 3 300 x 300 3 Q =6.94 x 10 -7

18-46 CHEM 102, Spring 2012 LA TECH To calculate  G o  G =  G o + RT ln Q  G o = -34 kJ/mole R = 8.314 J/K mole or 8.314 x 10 -3 kJ/Kmole T = 300 K Q= 6.94 x 10 -7  G = (-34 kJ/mole) + ( 8.314 x 10 -3 kJ/K mole) (300 K) ( ln 6.94 x 10 -7 )  G = -34 + 2.49 ln 6.94 x 10 -7  G = -34 + 2.49 x (-14.18)  G = -34 -35.37  G = -69.37 kJ/mole

18-47 CHEM 102, Spring 2012 LA TECH Calculate K (from  G 0 ) N 2 O 4 --->2 NO 2  G o rxn = +4.8 kJ  G o rxn = +4800 J = - (8.31 J/K)(298 K) ln K G o rxn = - RT lnK  G o rxn = - RT lnK K = 0.14 G o rxn > 0 : K 0 : K < 1 G o rxn 1  G o rxn 1 K = 0.14 G o rxn > 0 : K 0 : K < 1 G o rxn 1  G o rxn 1 Thermodynamics and K eq

18-48 CHEM 102, Spring 2012 LA TECH Concentrations, Free Energy, and the Equilibrium Constant The Influence of Temperature on Vapor Pressure H 2 O (l) => H 2 O (g) K eq = p water vapor p water vapor = K eq = e - G'/RT

18-49 CHEM 102, Spring 2012 LA TECH  G as a Function of the Extent of the Reaction

18-50 CHEM 102, Spring 2012 LA TECH  G as a Function of the Extent of the Reaction when there is Mixing

18-51 CHEM 102, Spring 2012 LA TECH Maximum Work  G = w system = - w max (work done on the surroundings)

18-52 CHEM 102, Spring 2012 LA TECH Coupled Reactions How to do a reaction that is not thermodynamically favorable? Find a reaction that offset the (+)  G Thermite Reaction Fe 2 O 3(s) => 2Fe (s) + 3/2O 2(g) 2Al (s) + 3/2O 2(g)  Al 2 O 3(s)

18-53 CHEM 102, Spring 2012 LA TECH ADP and ATP

18-54 CHEM 102, Spring 2012 LA TECH Acetyl Coenzyme A

18-55 CHEM 102, Spring 2012 LA TECH Gibbs Free Energy and Nutrients

18-56 CHEM 102, Spring 2012 LA TECH Photosynthesis: Harnessing Light Energy

18-57 CHEM 102, Spring 2012 LA TECH Using Electricity for reactions with (+)  G: Electrolysis Non spontaneous reactions could be made to take place by coupling with energy source: another reaction or electric current Electrolysis 2NaCl (l) => 2Na (s) + 2Cl 2(g)

18-1 CHEM 102, Spring 2012 LA TECH CTH 328 10:00-11:15 am Instructor: Dr. Upali Siriwardane Office: CTH 311 Phone 257-4941 Office.

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18-1 CHEM 102, Spring 2012 LA TECH CTH 328 10:00-11:15 am Instructor: Dr. Upali Siriwardane Office: CTH 311 Phone 257-4941 Office.

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Presentation on theme: "18-1 CHEM 102, Spring 2012 LA TECH CTH 328 10:00-11:15 am Instructor: Dr. Upali Siriwardane Office: CTH 311 Phone 257-4941 Office."— Presentation transcript:

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