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© University of South Carolina Board of Trustees 1 st -Order Rate Law Differential Form Rate = k [A]( t ) Integral Forms [A]( t ) = [A] 0 e - kt ln [A](

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Presentation on theme: "© University of South Carolina Board of Trustees 1 st -Order Rate Law Differential Form Rate = k [A]( t ) Integral Forms [A]( t ) = [A] 0 e - kt ln [A]("— Presentation transcript:

1 © University of South Carolina Board of Trustees 1 st -Order Rate Law Differential Form Rate = k [A]( t ) Integral Forms [A]( t ) = [A] 0 e - kt ln [A]( t ) = ln [A] 0 - k t y = b +mx y = b +mx

2 © University of South Carolina Board of Trustees Graphing a 1 st -Order Reaction

3 © University of South Carolina Board of Trustees Graphing a 1 st -Order Reaction

4 © University of South Carolina Board of Trustees Graphing a 1 st -Order Reaction straight line  this is a first-order reaction.

5 © University of South Carolina Board of Trustees [A] vs t Data  Rate Law Method of Initial Rates (Sec. 13.2)  Trial and Error with Common Laws (Sec. 13.3)

6 © University of South Carolina Board of Trustees ln [A] = ln [A] 0 - k t intercept = ln [A] 0

7 © University of South Carolina Board of Trustees ln [A] = ln [A] 0 - k t

8 © University of South Carolina Board of Trustees 1 st -Order Rate Law Differential Form Rate = k [A]( t ) Integral Forms [A]( t ) = [A] 0 e - kt ln [A]( t ) = ln [A] 0 - k t Half-life

9 © University of South Carolina Board of Trustees 1 st -Order Half-Life [A]  [A]/2 t 1/2

10 © University of South Carolina Board of Trustees 1 st -Order Half-Life [A]  [A]/2 t 1/2 5  2.51.75 s t 1/2

11 © University of South Carolina Board of Trustees 1 st -Order Half-Life [A]  [A]/2 t 1/2 5  2.51.75 s 3  1.51.72 s t 1/2

12 © University of South Carolina Board of Trustees Half-life [A]  [A]/2 t 1/2 5  2.51.75 s 3  1.51.72 s 1  0.51.73 s t 1/2

13 © University of South Carolina Board of Trustees 1 st -Order Rate Law Differential Form Rate = k [A]( t ) Integral Forms [A]( t ) = [A] 0 e - kt ln [A]( t ) = ln [A] 0 - k t Half-life always the same

14 © University of South Carolina Board of Trustees 1 st -Order Rate Law Differential Form Rate = k [A]( t ) Integral Forms [A]( t ) = [A] 0 e - kt ln [A]( t ) = ln [A] 0 - k t Half-life t 1/2 = ln 2 / k always the same

15 © University of South Carolina Board of Trustees Half-Life Problem I k = 6.2 x10 -5 s -1 for the reaction C 12 H 22 O 11 + H 2 O  C 6 H 12 O 6 + C 6 H 12 O 6 Calculate the half-life.

16 © University of South Carolina Board of Trustees 1 st -Order Rate Law Differential Form Rate = k [A]( t ) Integral Forms [A]( t ) = [A] 0 e - kt ln [A]( t ) = ln [A] 0 - k t Half-life t 1/2 = ln 2 / k always the same

17 © University of South Carolina Board of Trustees Common Rate Laws A  products a) First-order Rate = k [A] b) Second-order Rate = k [A] 2 c) Zero-order Rate = k [A] 0 = k

18 © University of South Carolina Board of Trustees 2 nd -Order Rate Law Differential Form Rate = k [A]( t ) 2

19 © University of South Carolina Board of Trustees 2 nd -Order Rate Law Differential Form Rate = k [A]( t ) 2 Integral Form

20 © University of South Carolina Board of Trustees Graphing a 2 nd -Order Reaction

21 © University of South Carolina Board of Trustees Graphing a 2 nd -Order Reaction not a straight line not a first-order reaction

22 © University of South Carolina Board of Trustees 2 nd -Order Rate Law Differential Form Rate = k [A]( t ) 2 Integral Form y = b + mx

23 © University of South Carolina Board of Trustees 1/ [A] = 1/ [A] 0 + k t straight line  this is a second- order reaction

24 © University of South Carolina Board of Trustees 1/ [A] = 1/ [A] 0 + k t 1/[A] 0 intercept = 1/[A] 0

25 © University of South Carolina Board of Trustees 1/ [A] = 1/ [A] 0 + k t yy xx 1/[A] 0

26 © University of South Carolina Board of Trustees 2 nd -Order Rate Law Differential Form Rate = k [A]( t ) 2 Half-life Integral Form

27 © University of South Carolina Board of Trustees 2 nd -Order Half-Life [A]  [A]/2 t 1/2

28 © University of South Carolina Board of Trustees 2 nd -Order Half-Life 1.0 s [A]  [A]/2 t 1/2 5  2.51.0 s

29 © University of South Carolina Board of Trustees 2 nd -Order Half-Life 4.7 s [A]  [A]/2 t 1/2 5  2.51.0 s 1  0.5 1  0.54.7 s

30 © University of South Carolina Board of Trustees 2 nd -Order Half-Life 4.7 s [A]  [A]/2 t 1/2 1.0 s 5  2.51.0 s 1  0.5 1  0.54.7 s reaction gets ‘slower’ as it proceeds

31 © University of South Carolina Board of Trustees 2 nd -Order Rate Law Differential Form Rate = k [A]( t ) 2 Half-life t 1/2 = 1 / k [A] varies - not so useful Integral Form

32 © University of South Carolina Board of Trustees Example: 2 nd -Order Reaction The reaction 2NOCl  2NO + Cl 2 obeys the rate law Rate = (0.020 M -1 s -1 ) [NOCl] 2 Calculate the concentration of NOCl after 30 minutes, if the initial concentration was 0.050 M.

33 © University of South Carolina Board of Trustees Common Rate Laws A  products a) First-order Rate = k [A] b) Second-order Rate = k [A] 2 c) Zero-order Rate = k [A] 0 = k

34 © University of South Carolina Board of Trustees 0 th -Order Rate Law Differential Form Rate = k [A]( t ) 0 Rate = k

35 © University of South Carolina Board of Trustees 0 th -Order Rate Law Differential Form Rate = k [A]( t ) 0 Rate = k y = b + mx Integral Forms [A]( t ) = [A] 0 - kt

36 © University of South Carolina Board of Trustees Graphing a 0 th -Order Reaction straight line  this is a 0 th -order reaction.

37 © University of South Carolina Board of Trustees [A](t)=[A] 0 - kt yy xx

38 © University of South Carolina Board of Trustees 0 th -Order Rate Law Differential Form Rate = k [A]( t ) 0 Rate = k Half-life y = b + mx Integral Forms [A]( t ) = [A] 0 - kt

39 © University of South Carolina Board of Trustees 0 th -Order Rate Law Differential Form Rate = k [A]( t ) 0 Rate = k Half-life varies - not so useful Integral Forms [A]( t ) = [A] 0 - kt

40 © University of South Carolina Board of Trustees Summary: Differential Rate Laws Zero-Order First-Order Second-Order Rate vs Concentration

41 © University of South Carolina Board of Trustees Summary: Integral Rate Laws Zero-Order[A]( t ) = [A] 0 − kt First-Order[A]( t ) = [A] 0 e − kt Second-Order Concentration vs Time

42 © University of South Carolina Board of Trustees Summary: Graphical Tests Zero-Order[A]( t ) = [A] 0 − k t First-Orderln [A]( t ) = ln[A] 0 − k t Second-Order y = b + m x

43 © University of South Carolina Board of Trustees Summary: Half-Life Zero-Ordervaries First-Orderconstant: Second-Ordervaries

44 © University of South Carolina Board of Trustees Half-Life Problem II A sample of wood has 58% of the 14 C ( t 1/2 = 5730 yr) originally present. What is the age of the wood sample?

45 © University of South Carolina Board of Trustees Chapt. 13 Kinetics Sec. 4 Theory of the Rate Constant ( k )

46 © University of South Carolina Board of Trustees Bimolecular Rate Theory A + B  products Rate = k ( T ) [A][B] Experiment

47 © University of South Carolina Board of Trustees Bimolecular Rate Theory A + B  products Rate =frequency of collisions Rate = k ( T ) [A][B] Experiment

48 © University of South Carolina Board of Trustees Bimolecular Rate Theory A + B  products Rate =frequency of collisions( Z 0 [A][B]) Rate = pZ 0 e- [A][B] Theory Rate = k ( T ) [A][B] Experiment

49 © University of South Carolina Board of Trustees Bimolecular Rate Theory A + B  products Rate =frequency of collisions( Z 0 [A][B]) Rate = pZ 0 e- [A][B] Theory Rate = k ( T ) [A][B] Experiment correct conc. dependence rates much too large no temperature dependence

50 © University of South Carolina Board of Trustees k Changes with Temperature

51 © University of South Carolina Board of Trustees Activation Energy Diagram  G Thermodynamics Kinetics Reactants Products Transition State

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