Textbook Question
Cleavage of the following ether produces the alcohol and haloalkane only, regardless of how much HBr is used. Thinking about the mechanism of the reaction, explain why bromobenzene is not also a product of this reaction.
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Ch. 13 - Alcohols, Ethers and Related Compounds: Substitution and Elimination
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. 13 - Alcohols, Ethers and Related Compounds: Substitution and EliminationProblem 109
Mullins 1st EditionCh. 13 - Alcohols, Ethers and Related Compounds: Substitution and EliminationProblem 109Chapter 12, Problem 109
Triphenylphosphine and iodine can be used to convert alcohols to iodoalkanes. Suggest a mechanism for this reaction. [Triphenylphosphine first acts as a nucleophile in this reaction.]
Verified step by step guidance1
Identify the role of triphenylphosphine (PPh₃) as a nucleophile. In this reaction, triphenylphosphine will attack the iodine molecule (I₂), forming a phosphonium iodide intermediate.
Write the initial nucleophilic attack: PPh₃ + I₂ → PPh₃I⁺ + I⁻. This step involves the formation of a positively charged phosphonium ion and a negatively charged iodide ion.
Consider the alcohol (R-OH) as the next reactant. The alcohol will react with the phosphonium iodide intermediate. The oxygen atom in the alcohol acts as a nucleophile, attacking the phosphonium ion.
Illustrate the formation of an alkoxyphosphonium intermediate: R-OH + PPh₃I⁺ → R-O-PPh₃⁺ + I⁻. This step involves the displacement of the iodide ion by the alcohol, forming an alkoxyphosphonium ion.
Finally, describe the elimination step where the alkoxyphosphonium ion undergoes a nucleophilic substitution by the iodide ion, resulting in the formation of the iodoalkane (R-I) and triphenylphosphine oxide (PPh₃=O).
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Nucleophilic Substitution
Nucleophilic substitution is a fundamental organic reaction where a nucleophile replaces a leaving group in a molecule. In this context, triphenylphosphine acts as a nucleophile, attacking the iodine molecule to form a phosphonium iodide intermediate, which facilitates the conversion of alcohols to iodoalkanes.
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Nucleophiles and Electrophiles can react in Substitution Reactions.
Role of Triphenylphosphine
Triphenylphosphine is a versatile reagent in organic chemistry, often used as a nucleophile due to its lone pair of electrons on phosphorus. In this reaction, it initiates the process by attacking iodine, forming a reactive intermediate that aids in the transformation of alcohols into iodoalkanes.
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Formation of Iodoalkanes
The conversion of alcohols to iodoalkanes involves replacing the hydroxyl group with an iodine atom. This transformation typically proceeds through a series of steps, including the formation of an intermediate, which then reacts with the alcohol to produce the iodoalkane, facilitated by the phosphonium iodide formed earlier.
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Related Practice
Textbook Question
In Chapter 12, we learned that crown ethers were used to increase the rate of SN2 reactions (Assessment 12.80). Suggest a synthesis of 15-crown-5 using the reactions learned here in Chapter 13.
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Textbook Question
Predict the product(s) that would result when molecules (a)–(p) are allowed to react under the following conditions: (i) SOCl₂ ; (ii) PBr₃ ; (iii) SOCl₂ , NEt₃ (iv) 1. TsCl, Et₃N 2. NaCN; (v) 1. TsCl, Et₃N 2. NaOt-Bu (vi) H₂SO₄ (vii) HCl; (viii) HBr; (ix) PCC; (x) H₂CrO₄ , H₂O (xi) HOCl, H₂O (xii) HIO₄ If no reaction occurs, write 'no reaction.'
(o)
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Textbook Question
Predict the product(s) that would result when molecules (a)–(p) are allowed to react under the following conditions: (vii) HCl; (viii) HBr; If no reaction occurs, write 'no reaction.'
(o)
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Textbook Question
Another method for converting alcohols to chloroalkanes makes use of chlorotrimethylsilane (TMSCl) and DMSO. Suggest a mechanism for this reaction to form (a) a 1° chloroalkane and (b) a 3° chloroalkane. [The reaction begins by the reaction of DMSO and TMSCl and is analogous to the Swern oxidation.]
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Textbook Question
We explain in Chapter 24 that bisphenols can be oxidized to quinones.
(a) Calculate the oxidation numbers of C1 and C₂ in going from reactant to product.
(b) Provide a mechanism for this transformation. [The reaction begins like the alcohol oxidations of Section 13.9.]
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