Out of the two given ketones , A and B, which ketone will undergo bromination faster under acidic conditions is to be determined. Concept introduction: Alpha halogenation is the halogenation at the alpha carbon atom of an aldehyde or a ketone under acidic conditions. Under these conditions, a negatively charged enolate ion is highly basic and cannot exist at substantial concentrations. However, the alpha carbon atom of a ketone can still become electron-rich via acid-catalyzed keto-enol tautomerism. Under the acidic conditions, the first step is the protonation of carbonyl oxygen. In the second step, the acetate ions serve as a base and abstract an alpha proton from ketone; this yields an enol form. In the enol form, the alpha carbon is electron rich due to the small contribution by the resonance structure in which a negative charge and a lone pair of electrons are located on the alpha carbon. Alpha halogenation occurs only once as the electron withdrawing effect of bromine destabilizes the positive charge if the carbonyl oxygen gets protonated further. This reduces the chances of the second halogenation.

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Definition Definition Organic compounds that have a carbonyl group, C=O, as their functional group. The carbonyl group in aldehydes is placed at the end of the molecular structure, which means the C=O is attached to one hydrogen atom and an alkyl group or a benzene ring. Just like all the other homologous series in organic chemistry, the naming of aldehydes uses the suffix “-al”. The general molecular formula is C n H 2n O.

Chapter 10, Problem 10.10YT

Interpretation Introduction

Interpretation:

Out of the two given ketones, A and B, which ketone will undergo bromination faster under acidic conditions is to be determined.

Concept introduction:

Alpha halogenation is the halogenation at the alpha carbon atom of an aldehyde or a ketone under acidic conditions. Under these conditions, a negatively charged enolate ion is highly basic and cannot exist at substantial concentrations. However, the alpha carbon atom of a ketone can still become electron-rich via acid-catalyzed keto-enol tautomerism.

Under the acidic conditions, the first step is the protonation of carbonyl oxygen. In the second step, the acetate ions serve as a base and abstract an alpha proton from ketone; this yields an enol form. In the enol form, the alpha carbon is electron rich due to the small contribution by the resonance structure in which a negative charge and a lone pair of electrons are located on the alpha carbon. Alpha halogenation occurs only once as the electron withdrawing effect of bromine destabilizes the positive charge if the carbonyl oxygen gets protonated further. This reduces the chances of the second halogenation.

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Answer 2

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Definition Definition Organic compounds that have a carbonyl group, C=O, as their functional group. The carbonyl group in aldehydes is placed at the end of the molecular structure, which means the C=O is attached to one hydrogen atom and an alkyl group or a benzene ring. Just like all the other homologous series in organic chemistry, the naming of aldehydes uses the suffix “-al”. The general molecular formula is C n H 2n O.

Chapter 10, Problem 10.10YT

Interpretation Introduction

Interpretation:

Out of the two given ketones, A and B, which ketone will undergo bromination faster under acidic conditions is to be determined.

Concept introduction:

Alpha halogenation is the halogenation at the alpha carbon atom of an aldehyde or a ketone under acidic conditions. Under these conditions, a negatively charged enolate ion is highly basic and cannot exist at substantial concentrations. However, the alpha carbon atom of a ketone can still become electron-rich via acid-catalyzed keto-enol tautomerism.

Under the acidic conditions, the first step is the protonation of carbonyl oxygen. In the second step, the acetate ions serve as a base and abstract an alpha proton from ketone; this yields an enol form. In the enol form, the alpha carbon is electron rich due to the small contribution by the resonance structure in which a negative charge and a lone pair of electrons are located on the alpha carbon. Alpha halogenation occurs only once as the electron withdrawing effect of bromine destabilizes the positive charge if the carbonyl oxygen gets protonated further. This reduces the chances of the second halogenation.

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Answer 3

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Definition Definition Organic compounds that have a carbonyl group, C=O, as their functional group. The carbonyl group in aldehydes is placed at the end of the molecular structure, which means the C=O is attached to one hydrogen atom and an alkyl group or a benzene ring. Just like all the other homologous series in organic chemistry, the naming of aldehydes uses the suffix “-al”. The general molecular formula is C n H 2n O.

Chapter 10, Problem 10.10YT

Interpretation Introduction

Interpretation:

Out of the two given ketones, A and B, which ketone will undergo bromination faster under acidic conditions is to be determined.

Concept introduction:

Alpha halogenation is the halogenation at the alpha carbon atom of an aldehyde or a ketone under acidic conditions. Under these conditions, a negatively charged enolate ion is highly basic and cannot exist at substantial concentrations. However, the alpha carbon atom of a ketone can still become electron-rich via acid-catalyzed keto-enol tautomerism.

Under the acidic conditions, the first step is the protonation of carbonyl oxygen. In the second step, the acetate ions serve as a base and abstract an alpha proton from ketone; this yields an enol form. In the enol form, the alpha carbon is electron rich due to the small contribution by the resonance structure in which a negative charge and a lone pair of electrons are located on the alpha carbon. Alpha halogenation occurs only once as the electron withdrawing effect of bromine destabilizes the positive charge if the carbonyl oxygen gets protonated further. This reduces the chances of the second halogenation.

Expert Solution & Answer

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Check out a sample textbook solution

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Answer 4

Question

Definition Definition Organic compounds that have a carbonyl group, C=O, as their functional group. The carbonyl group in aldehydes is placed at the end of the molecular structure, which means the C=O is attached to one hydrogen atom and an alkyl group or a benzene ring. Just like all the other homologous series in organic chemistry, the naming of aldehydes uses the suffix “-al”. The general molecular formula is C n H 2n O.

Chapter 10, Problem 10.10YT

Interpretation Introduction