Textbook Question
Predict the product when the dihydroxybenzene shown is treated with a single equivalent of both base and haloalkane.
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Ch. 24 - Benzene II: Reactions Influenced by the Aromatic Ring
Mullins1st EditionOrganic Chemistry: A Learner Centered ApproachISBN: 9780137566471
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Table of contents
- Ch. 2 - General Chemistry Translated: Finding the Electrons114
- Ch. 3 - Alkanes and Cycloalkanes: Properties and Conformational Analysis109
- Ch. 4 - Acids and Bases: Electron Flow144
- Ch. 5 - Chemical Reaction Analysis: Thermodynamics and Kinetics118
- Ch. 6 - Stereoisomerism: Arrangement of Atoms in Space112
- Ch. 7 - Principles of Green (Organic) Chemistry3
- Ch. 8 - Alkenes I: Properties and Electrophilic Additions158
- Ch. 9 - Alkenes II: Oxidation and Reduction150
- Ch. 10 - Alkynes: Electrophilic Addition and Redox Reactions101
- Ch. 11 - Properties and Synthesis of Alkyl Halides: Radical Reactions108
- Ch. 12 - Substitution and Elimination: Reactions of Haloalkanes172
- Ch. 13 - Alcohols, Ethers and Related Compounds: Substitution and Elimination239
- Ch. 14 - Structural Identification I: Infrared Spectroscopy and Mass Spectrometry54
- Ch. 15 - Structural Identification II: Nuclear Magnetic Resonance Spectroscopy93
- Ch. 16 - Metals in Organic Chemistry48
- Ch. 17 - Carbonyl Addition Reactions: Aldehydes and Ketones45
- Ch. 18 - Nucleophilic Acyl Substitution I: Carboxylic Acids18
- Ch. 19 - Nucleophilic Acyl Substitution II: Carboxylic Acid Derivatives39
- Ch. 20 - Enolates: Carbonyl Addition and Substitution13
- Ch. 21 - Conjugated Systems I: Stability and Addition Reactions56
- Ch. 22 - Conjugated Systems II: Pericyclic Reactions54
- Ch. 23 - Benzene I: Aromatic Stability and Substitution Reactions64
- Ch. 24 - Benzene II: Reactions Influenced by the Aromatic Ring62
- Ch. 25 - Amines: Structure, Reactions, and Synthesis27
- Ch. 26 - Amino Acids, Proteins, and Peptide Synthesis9
- Ch. 27 - Carbohydrates, Nucleic Acids, and Lipids54
Mullins1st EditionOrganic Chemistry: A Learner Centered ApproachISBN: 9780137566471Not the one you use?Change textbook
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Mullins 1st EditionCh. 24 - Benzene II: Reactions Influenced by the Aromatic RingProblem 21
Mullins 1st EditionCh. 24 - Benzene II: Reactions Influenced by the Aromatic RingProblem 21Chapter 23, Problem 21
In light of Figure 24.22, provide a mechanism by which para-dihydroxybenzene is oxidized to para-quinone.
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Identify the starting material as para-dihydroxybenzene, which has two hydroxyl groups attached to a benzene ring in the para position.
Recognize the oxidizing agent as chromic acid (H₂CrO₄), which is commonly used to oxidize alcohols to carbonyl compounds.
Understand that the mechanism involves the oxidation of the hydroxyl groups to carbonyl groups, forming para-quinone.
Propose that the first step involves the formation of a chromate ester intermediate, where the hydroxyl oxygen attacks the chromium atom, forming a bond and releasing water.
Suggest that the chromate ester undergoes a two-electron oxidation, where the C-O bond is cleaved, forming a carbonyl group and reducing the chromium species, resulting in the formation of para-quinone.
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Oxidation-Reduction Reactions
Oxidation-reduction (redox) reactions involve the transfer of electrons between species, leading to changes in oxidation states. In the context of organic chemistry, oxidation often refers to the loss of hydrogen or the gain of oxygen, while reduction is the opposite. Understanding these processes is crucial for analyzing how para-dihydroxybenzene can be converted to para-quinone through the removal of electrons and protons.
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Distinguishing between Oxidation and Reduction
Mechanism of Electrophilic Aromatic Substitution
Electrophilic aromatic substitution (EAS) is a fundamental reaction mechanism in organic chemistry where an electrophile replaces a hydrogen atom on an aromatic ring. In the case of para-dihydroxybenzene, the hydroxyl groups can activate the ring towards electrophilic attack, facilitating the formation of para-quinone. Recognizing the role of substituents in directing the reaction is essential for understanding the mechanism involved.
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Resonance and Stability of Intermediates
Resonance refers to the delocalization of electrons within a molecule, which can stabilize reaction intermediates. In the oxidation of para-dihydroxybenzene, the formation of a resonance-stabilized carbocation intermediate is key to the reaction pathway. Understanding how resonance affects the stability of intermediates helps predict the feasibility and outcome of the oxidation process leading to para-quinone.
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Related Practice
Textbook Question
Predict the product of the following substitution/addition reactions involving phenoxides.
(a)
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Textbook Question
Assessment 24.22 asked why meta-dihydroxybenzene could not be oxidized to meta-quinone. The attempted oxidation instead gives rise to three different quinone products. Suggest a mechanism for the formation of each.
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Textbook Question
Oxidation of a phenol derivative produces the lactone shown. Provide an arrow-pushing mechanism that rationalizes this outcome.
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Textbook Question
(a) Based on Figure 24.23, explain why meta-dihydroxybenzene is not oxidized to meta-quinone.
(b) If a meta-quinone is not produced, what would you expect the product of the oxidation of meta-dihydroxybenzene to be?
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Textbook Question
Predict the product of the following substitution/addition reactions involving phenoxides. [Because this problem represents a review of current and previous material, section numbers have been provided for your reference.]
(d)
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