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ChE 553 Lecture 25

ChE 553 Lecture 25. Theory Of Activation Barriers. Objective. Describe more quantitative models of activation barriers Marcus Blowers-Masel Show one can get reasonable estimates of activation barriers. Review: Barriers To Reaction Are Caused By. Uphill reactions

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ChE 553 Lecture 25

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  1. ChE 553 Lecture 25 Theory Of Activation Barriers

  2. Objective • Describe more quantitative models of activation barriers • Marcus • Blowers-Masel • Show one can get reasonable estimates of activation barriers

  3. Review: Barriers To Reaction Are Caused By • Uphill reactions • Bond stretching and distortion. • Orbital distortion due to Pauli repulsions. • Quantum effects. • Special reactivity of excited states.

  4. Polayni’s Model • Assumptions • Bond stretching dominates • Ignore Pauli repulsions, quantum effects • Linearize energy vs bond stretch • Result Ea varies linearly with heat of reaction • Only fair approximation to data

  5. Seminov Approximation: Use Multiple Lines Figure 11.12 A comparison of the activation energies of 482 hydrogen transfer reactions to those predicted by the Seminov relationships, over a wider range of energies. Figure11.11 A comparison of the activation energies of a number of hydrogen transfer reactions to those predicted by the Seminov relationships, equations (11.33) and (11.34)

  6. Marcus Model • Assumptions • Bond stretching dominates • Ignore Pauli repulsions, quantum effects • Parabolic energy vs bond stretch • Prediction

  7. Figure 10.13 An approximation to the change in the potential energy surface which occurs when Hr changes. Derivation: Fit Potentials To Parabolas Not Lines

  8. Figure 10.13 An approximation to the change in the potential energy surface which occurs when Hr changes. Derivation

  9. Solving (10.23) (10.24) Result (10.33) (10.31)

  10. Qualitative Features Of The Marcus Equation Figure 10.11 A Polanyi plot for the enolization of NO2(C6H4)O(CH2)2COCH3. Data of Hupke and Wu[1977]. Note Ln (kac) is proportional to Ea.

  11. Figure 10.17 The activation energy for intramolecular electron transfer across a spacer molecule plotted as a function of the heat of reaction. Data of Miller et. al., J. Am. Chem. Soc., 106 (1984) 3047. Marcus Is Great For Unimolecular Reactions

  12. Figure 10.18 The activation energy for florescence quenching of a series of molecules in acetonitrite plotted as a function of the heat of reaction. Data of Rehm et. al., Israel J. Chem. 8 (1970) 259. Marcus Not As Good For Bimolecular Reactions

  13. Figure 10.29 A comparison of the barriers computed from Blowers and Masel's model to barriers computed from the Marcus equation and to data for a series of reactions of the form R + HR1 RH + R1 with wO = 100 kcal/mole and = 10 kcal/mole. Comparison To Wider Bimolecular Data Set

  14. Why Inverted Behavior? At small distances bonds need to stretch to to TS.

  15. Limitations Of The Marcus Equation • Assumes that the bond distances in the molecule at the transition state does not change as the heat of reaction changes • Good assumption for unimolecular reactions • In bimolecular reactions bonds can stretch to lower barriers

  16. Explains Why Marcus Better For Unimolecular Than Bimolecular

  17. Blowers-Masel Equation • Assumptions • Bimolecular reaction • Pauli repulsions important • Include bond stretching but ignore quantum limitations

  18. Blowers-Masel Derivation • Fit potential energy surface to empirical equation. • Solve for saddle point energy. • Only valid for bimolecular reaction.

  19. Blowers-Masel Derivation Approximate VE by:

  20. Figure 10.28 A potential energy surface calculated from equation (10.59) with wCC = 95 kcal/mole, wCH = 104 kcal/mole, VP = 300 kcal/mole, qCC = 0.7, qCH = 0.5. Plot Of Potential

  21. Derive Analytical Expression (10.63) Bond energies (10.64) Only parameter (10.65)

  22. Figure 10.29 A comparison of the barriers computed from Blowers and Masel's model to barriers computed from the Marcus equation and to data for a series of reactions of the form R + HR1 RH + R1 with wO = 100 kcal/mole and = 10 kcal/mole. Comparison To Experiments

  23. Figure 10.32 A comparison of the Marcus Equation, The Polanyi relationship and the Blowers Masel approximation for =9 kcal/mole and wO = 120 kcal/mole. Comparison Of Methods

  24. Example: Activation Barriers Via The Blowers-Masel Approximation

  25. Solution: Step 1 Calculate VP VP is given by: (11.F.2)

  26. Step 1 Continued Substituting into equation (11.F.2) shows (11.F.3)

  27. Step 2: Plug Into Equation 11.F.1 (11.F.1) By comparison the experimental value from Westley is 9.6 kcal/mole.

  28. Solve Via The Marcus Equation: (11.F.4) which is the same as the Blowers-Masel approximation.

  29. Figure 10.39 A hypothetical four-centered mechanism for H2/D2 exchange. The dotted lines in the figure denotes mirror planes which are preserved during the reaction (see the text). This reaction is symmetry forbidden. Limitation Of The Model: Quantum Effects: Note one electron has to be spin up and spin down at the same time.

  30. Consider H2 + D2 2 HD HD HD H2 D2

  31. Can Reaction Occur? No Net Force To Distort Orbitals Net Force, but product is HD + H + D (i.e. two atoms) Such a reaction is 104 kcal/mole endothermic

  32. Conservation Of Orbital Symmetry • Quantum effect leading to activation barriers • Orbital symmetry/sign conserved during concerted reactions • Sometimes bonds must break before new bonds can form

  33. Figure 10.40 A schematic of the key molecular orbitals for the transition state of reaction (10.92). Positive atomic orbitals are depicted as open circles, negative orbitals are depicted as shaded circles. Orbital Diagram Symmetry forbidden reactions Woodward hoffman rules

  34. Summary • Bonds need to stretch or distort during reaction. It costs energy to stretch or distort bonds. Bond stretching and distortion is one of the major causes of barriers to reaction. • In order to get molecules close enough to react, the molecules need to overcome Pauli repulsions (i.e., electron electron repulsions) and other steric effects. The Pauli repulsions are another major cause of barriers to reaction.

  35. Summary Continued • In certain special reactions, there are quantum effects which prevent the bonds in the reactants from converting smoothly from the reactants to the products. Quantum effects can produce extra barriers to reaction. • There are also a few special cases where the reactants need to be promoted into an excited state before a reaction can occur. The excitation energy provides an additional barrier to reaction.

  36. Summary Continued Polayni: linear potential Marcus: parabolic potential Blowers-Masel – size of TST varies Fails with quantum effects ( varies)

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