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Chapter 18: Q24. (page 949)

Propose a mechanism for the acid-catalyzed reaction of benzaldehyde with methanol to give benzaldehyde dimethyl acetal.

Short Answer

Expert verified

The mechanism for the acid-catalyzed reaction of benzaldehyde with methanol to produce benzaldehyde dimethyl acetal is shown below.

Step by step solution

01

Formation of Acetal

When aldehydes and ketones react with alchols in the presence of acid, they form acetal as the major product. The formation of acetal can be divided into two simpler process namely (i) acid catalyzed addition of alcohol to the carbonyl group and (ii) SN1substitution of the hemiacetal that is protonated.

02

Mechanism for the Acid-catalyzed Reaction of Benzaldehyde with Methanol

Benzaldehyde reacts with methanol in the presence of acid to form benzaldehyde dimethyl aacetal. The corresponding reaction is shown below.

The meachanism for the acid-catalyzed reaction of benzaldehyde with methanol to produce benzaldehyde dimethyl acetal is shown below.

Step (a) Protonation of benzaldehyde

Step (b) Addition of an alcohol ( methanol)

Step (c) Deprotonation

Step (d) Protonation

Step (e) Loss of water

Step (f) Addition of second alcohol

Step (g) Deprotonation

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Most popular questions from this chapter

Sodium triacetoxyborohydride, NaBHOAc3, is a mild reducing agent that reduces aldehydes more quickly than ketones. It can be used to reduce aldehydes in the presence of ketones, such as in the following reaction:

(a) Draw a complete Lewis structure for sodium triacetoxyborohydride.

(b) Propose a mechanism for the reduction of an aldehyde by sodium triacetoxyborohydride.

Trimethylphosphine is a stronger nucleophile than triphenylphosphine, but it is rarely used to make ylides. Why is trimethylphosphine unsuitable for making most phosphorus ylides?

Show a complete mechanism for this equilibrium established in diethyl ether with HCl gas as catalyst.

Question: The family of macrolide antibiotics all have large rings (macrocycle) in which an ester is what makes the ring; a cyclic ester is termed as a lactone. One example is amphotericin B, used as an anti-fungal treatment of last resort because of its liver and heart toxicity. Professor Martin Burke of the University of Illnois has been making analogs to retain the antifungal properties but without the toxicity, including this structure published in 2015. (Nature Chemical Biology, (2015) doi: 10.1038/nchembio.1821). The carboxylate of amphotericin B has been replaced with the urea group (shown in red).

(a) Where is the lactone group that forms the ring?

(b) Two groups are circled. What type of functional group are they? Explain.

Show how you would accomplish the following synthesis.

(a) Acetphenone→ acetophenone cyanohydrin

(b) Cyclopentancarbaldehyde→ 2-cyclopentyl-2-hydroxyacetic acid

(c) Hexan-1-ol →2-hydroxyheptanoic acid
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