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Nucleophilic Substitutions of Alkyl Halides

This chapter explores the reactions of alkyl halides with nucleophiles and bases, including the SN2 and SN1 mechanisms. It also discusses factors affecting the rates of substitution reactions and the reactivity of substrates and nucleophiles.

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Nucleophilic Substitutions of Alkyl Halides

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  1. Chapter 7-2. Reactions of Alkyl Halides: Nucleophilic Substitutions Based on McMurry’s Organic Chemistry, 6th edition

  2. Polarity and Reactivity • Halogens are more electronegative than C. • Carbon-halogen bond is polar, so carbon has partial positive charge. • Carbon can be attacked by a nucleophile. • Halogen can leave with the electron pair.

  3. Alkyl Halides React with Nucleophiles and Bases • Alkyl halides are polarized at the carbon-halide bond, making the carbon electrophilic • Nucleophiles will replace the halide in C-X bonds of many alkyl halides (reaction as Lewis base)

  4. Alkyl Halides React with Nucleophiles and Bases • Nucleophiles that are Brønsted bases produce elimination

  5. Substitution vs. Elimination

  6. The Nature of Substitution • Substitution requires that a "leaving group", which is also a Lewis base, departs from the reacting molecule. • A nucleophile is a reactant that can be expected to participate as a Lewis base in a substitution reaction.

  7. SN2 Mechanism • One step: bond forming and bond breaking at same time. “concerted” process • Bimolecular nucleophilic substitution. • Rate = k [HO-] [CH3Br], first order in each reactant second order overall • Inversion of configuration.

  8. Kinetics of Nucleophilic Substitution Rate = d[CH3Br]/dt = k[CH3Br][OH-1] This reaction is second order: two concentrations appear in the rate law SN2: Substitution Nucleophilic 2nd order

  9. => SN1 Mechanism(1) Formation of carbocation (slow)

  10. SN1 Mechanism (2) • Nucleophilic attack • Loss of H+ (if needed)

  11. SN1 Energy Diagram • Forming the carbocation is endothermic • Carbocation intermediate is in an energy well.

  12. SN1 Mechanism • Unimolecular nucleophilic substitution. • Two step reaction with carbocation intermediate. • Rate = k [RX] first order in the alkyl halidezero order in the nucleophile. • Racemization occurs.

  13. Factors affecting the rates of SN Reactions • Concentration • Nature of the alkyl group • Nature of the nucleophile • Nature of the leaving group • Nature of the solvent

  14. Structure of Substrate • Relative rates for SN2: CH3X > 1° > 2° >> 3° • Tertiary halides do not react via the SN2 mechanism, due to steric hindrance.

  15. SN2: Reactivity of Substrate • Carbon must be partially positive. • Must have a good leaving group • Carbon must not be sterically hindered.

  16. The Nucleophile • Neutral or negatively charged Lewis base • Reaction increases coordination (adds a new bond) at the nucleophile • Neutral nucleophile acquires positive charge • Anionic nucleophile becomes neutral

  17. For example:

  18. Relative Reactivity of Nucleophiles • Depends on reaction and conditions • More basic nucleophiles react faster • Better nucleophiles are lower in a column of the periodic table • Anions are usually more reactive than neutrals

  19. Nucleophilic Strength • Stronger nucleophiles react faster in SN2. • Strong bases are strong nucleophiles, but not all strong nucleophiles are basic.

  20. Bulky Nucleophiles Sterically hindered for attack on carbon, so weaker nucleophiles.

  21. Trends in Nuc. Strength • Decreases left to right on Periodic Table. More electronegative atoms less likely to form new bond: OH- > F-NH3 > H2O • Increases down Periodic Table, as size and polarizability increase: I- > Br- > Cl- • Of a conjugate acid-base pair, the base is stronger: OH- > H2O, NH2- > NH3

  22. Polarizability Effect

  23. The Leaving Group • A good leaving group reduces the energy of activation of a reaction • Stable anions that are weak bases (conjugate bases of strong acids) are usually excellent leaving groups • Stronger bases (conjugate bases of weaker acids) are usually poorer leaving groups

  24. Leaving Group Ability • Electron-withdrawing • Stable once it has left (not a strong base) • Polarizable to stabilize the transition state.

  25. Poor Leaving Groups • If a group is very basic or very small, it does not undergo nucleophilic substitution.

  26. Solvent Effects (1) Polar protic solvents (O-H or N-H) reduce the strength of the nucleophile. Hydrogen bonds must be broken before nucleophile can attack the carbon.

  27. Solvent Effects (2) • Polar aprotic solvents (no O-H or N-H) do not form hydrogen bonds with nucleophile • Examples:

  28. Rates of SN1 Reactions • 3° > 2° > 1° >> CH3X • Order follows stability of carbocations (opposite to SN2) • More stable ion requires less energy to form • Better leaving group, faster reaction (like SN2) • Polar protic solvent best: It solvates ions strongly with hydrogen bonding.

  29. The Discovery of the Walden Inversion • In 1896, Paul Walden showed that (-)-malic acid could be converted to (+)-malic acid by a series of chemical steps with achiral reagents • This established that optical rotation was directly related to chirality and that it changes with chemical alteration • Reaction of (-)-malic acid with PCl5 gives (+)-chlorosuccinic acid • Further reaction with wet silver oxide gives (+)-malic acid • The reaction series starting with (+) malic acid gives (-) acid

  30. Stereochemistry of SN2 Walden inversion SN2: Substitution Nucleophilic 2nd order

  31. SN2 Energy Diagram • One-step reaction. • Transition state is highest in energy.

  32. SN2 Transition State • The transition state of an SN2 reaction has a planar arrangement of the carbon atom and the remaining three groups • Hybridization is sp2

  33. Stereochemistry of SN1 Racemization: inversion and retention =>

  34. Two Stereochemical Modes of Substitution • Substitution with inversion: • Substitution with retention:

  35. The Walden Inversion (1896)

  36. Significance of the Walden Inversion • The reactions involve substitution at the chiral center • Therefore, nucleophilic substitution can invert the configuration at a chirality center

  37. Stereochemistry of Nucleophilic Substitution • A more rigorous Walden cycle using 1-phenyl-2-propanol (Kenyon and Phillips, 1929) • Only the second and fifth steps are reactions at carbon • Inversion must occur in the substitution step

  38. Hughes’ Proof of Inversion • React (S)-2-iodo-octane with radioactive iodide • Observe that racemization (loss of optical activity) of mixture is twice as fast as incorporation of label • Racemization in one reaction step would occur at same rate as incorporation

  39. Hughes’ Proof of Inversion

  40. Rearrangements • Carbocations can rearrange to form a more stable carbocation. • Hydride shift: H- on adjacent carbon bonds with C+. • Methyl shift: CH3- moves from adjacent carbon if no H’s are available.

  41. Hydride Shift

  42. Methyl Shift

  43. Primary or methyl Strong nucleophile Polar aprotic solvent Rate = k[halide][Nuc] Inversion at chiral carbon No rearrangements Tertiary Weak nucleophile (may also be solvent) Polar protic solvent, silver salts Rate = k[halide] Racemization of optically active compound Rearranged products SN2 or SN1?

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