Chapter 12, Problem 12.24P

Interpretation Introduction

(a)

Interpretation:

The steps to carry out the given transformation is to be shown.

Concept introduction:

An alkene can be converted to an alcohol in many ways, out of which, the oxymercuration-reduction and an acid-catalyzed hydration reaction follows Markovnikov’s regiochemistry while hydroboration-oxidation follows anti Markovnikov’s regiochemistry. In hydroboration-oxidation, the partially negative hydrogen atom forms a bond with most substituted carbon while the boron ends up attached to the least substituted carbon atom. In the final product, the $\text{C}-\text{B}$ bond is replaced by the $\text{C}-\text{OH}$ bond.

Interpretation Introduction

(b)

Interpretation:

The steps to carry out the given transformation is to be shown.

Concept introduction:

An alkene can be converted to an alcohol in many ways, out of which, the oxymercuration-reduction, and an acid-catalyzed hydration reaction follows Markovnikov’s regiochemistry. The oxymercuration-reduction does not go through the carbocation intermediate, so no carbocation rearrangements occur with this mechanism. On the other hand, carbocation rearrangements are possible in acid-catalyzed addition of water. The product of oxymercuration-reduction is the one expected from Markovnikov’s rule, that is, the $-\text{OH}$ group forms a bond with the carbon atom that can better stabilize a positive charge. Rearrangement generally does not take place with oxymercuration–reduction.

Interpretation Introduction

(c)

Interpretation:

The steps to carry out the given transformation is to be shown.

Concept introduction:

An alkene can be converted to an alcohol in many ways, out of which, the oxymercuration-reduction, and an acid-catalyzed hydration reactions follow Markovnikov’s regiochemistry. The oxymercuration-reduction does not go through the carbocation intermediate, so no carbocation rearrangements occur with this mechanism. On the other hand, carbocation rearrangements are possible in acid-catalyzed addition of water. The product of oxymercuration-reduction is the one expected from Markovnikov’s rule, that is, the $-\text{OH}$ group forms a bond to the carbon atom that can better stabilize a positive charge. Rearrangement generally does not take place with oxymercuration–reduction.