MS 935 - Enols and Enolates

MS 935 - Enols and Enolates

Textbook and Chapter: Carey and Giuliano 8th Ed. (2010), Chapter 20

Keyword: carbonyl alpha substitution

Description: Goes over how to form enols/enolates under acidic and basic conditions, and how enols/enolates react.

Total Problems: 6

  1. Problem # 738

    Carbonyls are in equilibrium with their enol forms. This process is called keto-enol tautomerization.

    This equilibrium happens in both acid and base.

    Let's go through this equilibrium under acidic conditions. Draw a mechanism using curved arrows for each reaction below.

    Remember that under acidic conditions, most species are either neutral or positively charged, and rarely negatively charged. So your structures will contain either ROH or ROH2+, but not RO-.

     

    a) Carbonyl to Enol (acidic)

     

    b) Enol to Carbonyl (acidic)

  2. Problem # 739

    Carbonyls are in equilibrium with their enol forms. An enolate is the deprotonated form of an enol.

    Enolates are formed from carbonyls under basic conditions.

    Let's go through this equilibrium under basic conditions. Draw a mechanism using curved arrows for each reaction below.

    Remember that under basic conditions, most species are either neutral or negatively charged, and rarely positively charged. So your structures will contain either ROH or RO-, but not ROH2+.

     

    a) Carbonyl to Enolate (basic)

     

    b) Enolate to Carbonyl (basic)

  3. Problem # 740

    Enolates are formed from carbonyls by adding a strong base, such as lithium diisopropyl amide (LDA), to deprotonate the alpha position. The enolate can then act as a nucleophile and attack an electrophile (such as an alkyl halide), to form a new bond at the alpha position. This is called a carbonyl alpha substitution reaction.

     

    Let's go through the mechanism of how enolates are formed and how they react with electrophiles.

    Draw in the curved arrows to show the formation of the enolate (middle compound), and draw the structure of the carbonyl product (right compound)

     

  4. Problem # 741

    Like enolates (Q740), enols can also act as nucleophiles and make new bonds at the alpha position.

    Let's go through the mechanism for how this happens, using alpha bromination as our example.

    In the reaction below, the carbonyl form is in equilibrium with its enol form (Q738), which can then attack molecular bromine.

     

    Complete the structure of the protonated carbonyl, and show the curved arrows that transform it into the final carbonyl product.

  5. Problem # 742

    Enamines are similar to enols and enolates in that they also undergo alpha substitution reactions.

    The process of performing a carbonyl alpha substitution reaction via an enamine intermediate is called the Stork enamine synthesis. Let's work through this reaction.

     

    Draw in the structures for the enamine and show it attacking the alkyl halide to form the  "3º imine." Also draw the structure of the final and carbonyl product.

     

  6. Problem # 743
     

    Enolates are nucleophiles and react with a variety of electrophiles.

    Carbonyls are electrophiles. But aldehydes/ketones and  esters/acid chlorides often form different products.

     

    Use curved arrows to draw a mechanism for each reaction below. How do the two products differ?