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24.3: Base Catalysis

  • Page ID
    14142
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    It has been demonstrated that water, in the presence of an acid or a base, adds rapidly to the carbonyl function of aldehydes and ketones establishing a reversible equilibrium with a hydrate (geminal-diol or gem-diol). The word germinal or gem comes from the Latin word for twin, geminus.

    OrganicCore_AldehydesKetones63.png

    Example 1

    OrganicCore_AldehydesKetones64.png

    Going from Reactants to Products Simplified

    OrganicCore_AldehydesKetones65.png

    Reversibility of the Reaction

    Isolation of gem-diols is difficult because the reaction is reversibly. Removal of the water during a reaction can cause the conversion of a gem-diol back to the corresponding carbonyl.

    OrganicCore_AldehydesKetones66.png

    Factors Affecting the Gem-diol Equilibrium

    In most cases the resulting gem-diol is unstable relative to the reactants and cannot be isolated. Exceptions to this rule exist, one being formaldehyde where the weaker pi-component of the carbonyl double bond, relative to other aldehydes or ketones, and the small size of the hydrogen substituents favor addition. Thus, a solution of formaldehyde in water (formalin) is almost exclusively the hydrate, or polymers of the hydrate. The addition of electron donating alkyl groups stabilized the partial positive charge on the carbonyl carbon and decreases the amount of gem-diol product at equilibrium. Because of this ketones tend to form less than 1% of the hydrate at equilibrium. Likewise, the addition of strong electron-withdrawing groups destabilizes the carbonyl and tends to form stable gem-diols. Two examples of this are chloral, and 1,2,3-indantrione. It should be noted that chloral hydrate is a sedative and has been added to alcoholic beverages to make a “Knock-out” drink also called a Mickey Finn. Also, ninhydrin is commonly used by forensic investigators to resolve finger prints.

    OrganicCore_AldehydesKetones67.png

    Mechanism of Gem-diol Formation

    The mechanism is catalyzed by the addition of an acid or base. Note! This may speed up the reaction but is has not effect on the equilibriums discussed above. Basic conditions speed up the reaction because hydroxide is a better nucleophilic than water. Acidic conditions speed up the reaction because the protonated carbonyl is more electrophilic.

    Under Basic conditions

    1) Nucleophilic attack by hydroxide

    OrganicCore_AldehydesKetones68.png

    2) Protonation of the alkoxide

    OrganicCore_AldehydesKetones69.png

    Under Acidic conditions

    1) Protonation of the carbonyl

    OrganicCore_AldehydesKetones70.png

    2) Nucleophilic attack by water

    OrganicCore_AldehydesKetones71.png

    3) Deprotonation

    OrganicCore_AldehydesKetones72.png

    Problems

    1) Draw the expected products of the following reactions.

    OrganicCore_AldehydesKetones73.png

    2) Of the following pairs of molecules which would you expect to form a larger percentage of gem-diol at equilibrium? Please explain your answer.

    OrganicCore_AldehydesKetones74.png

    3) Would you expect the following molecule to form appreciable amount of gem-diol in water? Please explain your answer.


    OrganicCore_AldehydesKetones75.png

    Answers

    1)

    OrganicCore_AldehydesKetones76.png

    2) The compound on the left would. Fluorine is more electronegative than bromine and would remove more electron density from the carbonyl carbon. This would destabilize the carbonyl allowing for more gem-diol to form.

    3) Although ketones tend to not form gem-diols this compound exists almost entirely in the gem-diol form when placed in water. Ketones tend to not form gem-diols because of the stabilizing effect of the electron donating alkyl group. However, in this case the electron donating effects of alkyl group is dominated by the presence of six highly electronegative fluorines.

    Contributors


    24.3: Base Catalysis is shared under a CC BY-NC-SA 4.0 license and was authored, remixed, and/or curated by LibreTexts.

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