1 / 26

CHEM1612 - Pharmacy Week 12: Kinetics – Catalysis

CHEM1612 - Pharmacy Week 12: Kinetics – Catalysis. Dr. Siegbert Schmid School of Chemistry, Rm 223 Phone: 9351 4196 E-mail: siegbert.schmid@sydney.edu.au. Unless otherwise stated, all images in this file have been reproduced from:

kesler
Télécharger la présentation

CHEM1612 - Pharmacy Week 12: Kinetics – Catalysis

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. CHEM1612 - PharmacyWeek 12: Kinetics – Catalysis Dr. SiegbertSchmid School of Chemistry, Rm 223 Phone: 9351 4196 E-mail: siegbert.schmid@sydney.edu.au

  2. Unless otherwise stated, all images in this file have been reproduced from: Blackman, Bottle, Schmid, Mocerino and Wille,Chemistry, John Wiley & Sons Australia, Ltd. 2008      ISBN: 9 78047081 0866

  3. Endothermic reaction Ea (rev) Ea (forw) Ea (forw) C + D Ea (rev) A + B Larger Ea smaller k lower rate Energy Landscape in Chemical Reactions A + B C + D Exothermic reaction Activated state A + B Figure from Silberberg, “Chemistry”, McGraw Hill, 2006. C + D Forward reaction is faster than reverse Reverse reaction is faster than forward

  4. By the way: why the product? 2×2 =4 elementary reaction A + B→ C rate = k [A][B] Why does rate depend on the product of reactant concentrations? Rateproportional to the number of collisions of A and B No. collisions = product of the number or particles present 3×2 =6 3×3=9

  5. Transition State • If reactants come together with enough energy and the right orientation, they combine to form a transition state (or activated complex). • This species is half-way between the reactants and the products but is not neither. • Transition states are very unstable (cannot be isolated). Blackman Figure 14.10

  6. CH3Br + OH- CH3OH + Br - Transition State Nature of the transition state in the reaction between CH3Br and OH-. Figure from Silberberg, “Chemistry”, McGraw Hill, 2006. transition state or activated complex

  7. Reaction Energy Diagram Figure from Silberberg, “Chemistry”, McGraw Hill, 2006.

  8. Transition state in elementary steps k = A e – Ea / R T Ea1 > Ea2, therefore Ea1 is the slow step and Ea2 is the fast step. Two transition states. Blackman Figure 14.11

  9. Transition state in elementary steps Step 1 NO2 + F2 →NO2F + F Step 2 NO2 + F → NO2F Overall 2 NO2 + F2 → 2NO2F Figure from Silberberg, “Chemistry”, McGraw Hill, 2006.

  10. Catalysis • A catalyst increases the rate of a chemical reaction. • A catalyst is not consumed or changed in the overall process. • A catalyst provides an alternative reactionpathway of lower activation energy: more molecules have the minimum energy required for successful reaction and the reaction proceeds at a faster rate. k A + BC + D

  11. Catalysis • A catalyst speeds both the forward and reverse reaction, so does NOT affect the position of the equilibrium. • Does not change the equilibrium constant Keq = k1/k-1; even though k1 and k-1 may be much larger for the catalyzed reaction. • Does not change the G0 for the reaction. • A catalyst can be homogeneous(one phase with reactants and products) or heterogeneous (more than one). • Many catalysed reactions are zero-order. • A small quantity of catalyst affects the reaction rate for a large amount of reactant.

  12. Demo: Catalytic Decomposition of Hydrogen Peroxide Manganese dioxide MnO2 is used to catalyse the decomposition of H2O2. Prepare a slurry of MnO2 and NaOH, and add H2O2. The rapid decomposition of H2O2 occurs with production of a grey foam: 2 H2O2 → 2 H2O + O2

  13. Catalysis • Let’s look at the decomposition of H2O2 again. 2 H2O2(aq) 2 H2O(l) + O2(g) Catalyst Ea (kJ mol-1) Rel. rate of reaction None 75.3 1 I– 56.5 2.0 x 103 Pt 49.0 4.1 x 104 Catalase 8.0 6.3 x 1011 Bombardier beetle (Brachinus fumans)

  14. Homogeneous Catalysis • Let’s closely examine the reaction of H2O2 with I–: • Rate law: rate = k[H2O2][I–]. • Reaction occurs in two steps: Step 1: H2O2 + I– H2O+ IO– Step 2: H2O2 + IO– H2O+ O2(g) +I– • Note that I– regenerated during reaction and it does not appear in overall reaction. • I– acts as a homogeneous catalyst for H2O2 decomposition.

  15. A B Heterogeneous Catalysis • Heterogeneous catalysis: most important industrially. • Catalytic converters: First converter (A): Rh Catalyses: 2 NO(g) N2(g) + O2(g) Second converter (B): Pt/Pd Catalyses: 2 CO(g) + O2(g) 2 CO2(g) Catalytic converter

  16. The metal-catalyzed formation of ammonia Fe N2(g) + 3H2(g) → 2NH3(g) • Both substrates must bind to a free active site on the Fe surface before the reaction can proceed. • Increasing the concentration of either gas cannot increase the rate of reaction (i.e. rate independent of concentration).

  17. Enzymes • Catalysts of biological reactions • Complex 3D structure • Huge molar mass • Active site attracts substrates through intermolecular forces • Haber process (500 atmand 450 °C; Nitrogenase(1 atm and 25°C) Enzyme-substrate complex of elastase and small peptide

  18. Active site Structure of the enzyme Hexokinase from X-ray data. Enzymatic Catalysis • All enzymes are proteins, but not all proteins are enzymes. • Enzymes mustpossess catalytic activity. • The part of the enzyme tertiary structure that is responsible for the catalytic activity is known as the “active site”. • Each enzyme catalyses a singlechemical reaction on a specific • substrate molecule with high selectivity.

  19. Michaelis-Menten mechanism: enzyme-substrate complex ES. Enzymatic Catalysis • Efficient: rate enhancements of 108 to 1020 possible • Specific (one enzyme per reaction) • Low tolerance to temperature and pH changes • Lock-and-key model (E. Fischer, 1894) • Induced fit model (D. Koshland, 1958) Product + enzyme

  20. Enzymatic Catalysis • Hexokinasealters its conformation to fit around the substrate molecule (D-glucose). • Enzyme and substrate adapt to accommodate one another. • “Enzymes are molecules that are complementary in structure to the transition states of the reactions they catalyze”. • Linus Pauling (1948)

  21. Enzymatic Catalysis • Enzymes can distinguish between enantiomers: • Only one of the enantiomers can be used as a substrate for this enzyme.

  22. Free energy E – E = E D a(uncat) a(cat) a Enzymatic Catalysis ….. uncatalyzed reaction catalyzed reaction Reaction co-ordinate If DEa= 10 kJ mol-155-fold rate acceleration (at 25°C). If DEa= 20 kJ mol-13000-fold rate acceleration (at 25°C). If DEa= 40 kJ mol-1107-fold rate acceleration (at 25°C).

  23. Enzymatic Catalysis k = A e – Ea / R T • The Arrhenius equation indicates that in order to increase the rate of a reaction: • The temperature must be increased, • Ea must be decreased, and/or • The reactants must be positioned so as to maximise the reaction efficiency. • Increasing the temperature is not an option for most biological reactions, so the remaining options are exploited by Nature.

  24. Summary CONCEPTS • Elementary reactions, reaction mechanisms • Dependence of reaction rate on temperature and orientation • Arrhenius equation and its implications • Activation energy and transition states • Catalysis CALCULATIONS • Express reaction rate in terms of reactant/product concentrations • Derive rate law of a reaction from experimental data on reactant consumption/product formation • Derive rate law of a reaction, knowing its elementary steps • Calculate k, A, Tor Ea for a reaction using Arrhenius equation

  25. The Ozone System • In the atmosphere: • O2 + hn (<200 nm)  O + O k1 • O + O2  O3 assume very fast • O3 + hn(210-300 nm)  O2 + O k2 • O3 + O  2 O2 k3 • Kinetics very complicated since UV intensity will vary so much in time and place. • At equilibrium, rate of ozone creation and destruction will be the same: steady state approximation.

  26. The Ozone Hole • Chlorofluorocarbons provide an additional pathway for ozone decomposition. • CF2Cl2 + hn CF2Cl• + Cl• • Cl• + O3  ClO• + O2 removing ozone • ClO• + O•  Cl• + O2 • Cl is regenerated during the reaction • Cl will stick around until eventually reacts to HCl and is precipitated out.

More Related