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Chapter%2018%20Lecture%201%20Enols

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Title: Chapter%2018%20Lecture%201%20Enols


1
Chapter 18 Lecture 1 Enols
  • Enolate Ions
  • Carbonyl Reactivity
  • Nucleophilic carbonyl oxygen
  • Electrophilic carbonyl carbon
  • a-carbon containing acidic a-protons (the
    subject of this chapter)
  • Acidity of Aldehydes and Ketones
  • pKa of protons alpha to an aldehyde or ketone
    carbonyl 19-21
  • Ethene pKa 44
  • Ethyne pKa 25
  • Alcohol pKa 15-18
  • Strong bases can remove a-hydrogens to produce an
    Enolate Ion

Enolate Ion
2
  • Why are carbonyl a-protons acidic?
  • The conjugate base is stabilized by the enolate
    ion resonance structures
  • The d carbon of the carbonyl destabilizes the a
    CH bond
  • C. Formation of Enolate Ions
  • LDA (lithium diisopropyl amide) or other strong
    bases are used
  • Aprotic solvents are used to prevent solvent
    deprotonation
  • Enolate Resonance Hybrid
  • The a-carbon and the oxygen of an enolate ion are
    both nucleophilic
  • Ambident two-fanged a species that can
    react at 2 different sites to give 2 different
    products

3
  • The carbon atom is the normal site of reaction by
    SN2. This type of reaction is called alkylation
    or C1-alkylation of the enolate ion.
  • The oxygen atom is the normal site of
    protonation, forming an enol, which will
    tautomerize to the original ketone.
  • II. Keto-Enol Equilibria
  • KetoneEnol Tautomerization
  • This reaction is reversible, and the extent of
    reaction depends on conditions
  • Base-catalyzed Enol-Keto Equilibration
  • Base removes proton from the enol
  • The mechanism is the reverse of the original
    enolate formation

4
  • Acid Catalyzed Enol-Keto Equilibration
  • Protonation occurs at the double bond
  • Resonance stabilized C is next to O
  • Protonated carbonyl deprotonates to give the keto
    form
  • Both reaction are fast if the catalyst (B- or H)
    are present
  • Keto form is usually dominant
  • Keto to enol tautomerization mechanisms are the
    reverse of those above
  • Effects of Substituents on Keto-Enol Equilibria
  • Ketone donating substituents stabilize keto form
  • Aldehyde lack of donating substituents pushes
    equilibria toward enol form

5
  • Deuteration of Carbonyl a-Carbons
  • Dissolving an aldehyde or ketone in D2O, DO- (or
    D) replaces all of the a-Hydrogens with
    Deuteriums
  • Even though the keto form dominates, a small is
    always tautomerizing to the enol. Over time,
    reprotonation at C gives the fully deuterated
    product.
  • Reaction can be followed by 1H NMR as a-H signal
    disappears
  • Interconversion of a-C stereochemistry
  • 1) Keto-Enol tautomerization proceeds through an
    achiral intermediate

6
  • Loss of optical activity occurs under basic or
    acidic conditions
  • Halogenation of Aldehydes and Ketones
  • Acid-Catalyzed a-Halogenation of Ketones and
    Aldehydes
  • In acidic conditions, only one halogen is able to
    add
  • The reaction rate is independent of X2
    concentration, suggesting that the rate
    determining step depends only on the carbonyl
    compound

7
  • 3) Mechanism of acid catalyzed a monohalogenation
  • 4) Why does the reaction stop after only one
    halogenation?
  • Mechanism requires enolization
  • Electron withdrawing Br prevents protonation
    needed in first step

O is no longer basic enough To attack proton.
Enolization Cant happen.
8
  • Base Mediated Halogenation of a-Carbon Goes to
    Completion
  • Mechanism
  • Electron Withdrawing Br increases a-Hydrogen
    acidity, favoring complete bromination of all
    a-Carbons
  • The Iodoform test for Methyl Ketones is base
    catalyzed halogenation

9
  • Alkylation of Aldehydes and Ketones
  • Alkylation of Ketones Using NaH
  • Ketones with only one a-Hydrogen are alkylated in
    high yield
  • Example
  • NaH is a strong base yielding enolate ion when
    reacted with carbonyls
  • Polyalkylation occurs if multiple a-Hs are
    present

10
  • Unsymmetric Ketones give multiple products
  • Enamine Route to Ketone/Aldehyde Alkylation
  • Enamine formation makes CC bonds electron rich
    by resonance
  • The nucleophilic a-Carbon can then attack
    electrophiles

11
  • The amine is removed from the alkylated product
    by acid to give the alkylated ketone or aldehyde
  • The Enamine Alkylation Route is Preferred
  • No multiple alkylations
  • Works on Aldehydes and Ketones
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