Textbook Question
(a) Show how you would affect the following transformation using a tosylate.
(b) Why might this not be the most sustainable method?
(c) What reagent might you use instead?
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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 92b
Mullins 1st EditionCh. 13 - Alcohols, Ethers and Related Compounds: Substitution and EliminationProblem 92bChapter 12, Problem 92b
Using an appropriate tosylate intermediate, synthesize the following molecules starting from the appropriate alcohol.
(b) 
Verified step by step guidance1
Identify the starting alcohol: Analyze the target molecule to determine the appropriate alcohol that can be used as the starting material. The target molecule contains a thioether linkage, suggesting that the alcohol should be a primary alcohol with a similar carbon skeleton.
Convert the alcohol to a tosylate: React the identified alcohol with p-toluenesulfonyl chloride (TsCl) in the presence of a base like pyridine. This will convert the alcohol into a tosylate, which is a good leaving group.
Perform nucleophilic substitution: Use a thiol (R-SH) as the nucleophile to perform a nucleophilic substitution reaction on the tosylate. The thiol will replace the tosylate group, forming the thioether linkage present in the target molecule.
Ensure the correct carbon skeleton: Verify that the carbon skeleton of the starting alcohol matches the target molecule. If necessary, adjust the carbon chain length or branching before tosylation to ensure the final product has the correct structure.
Check stereochemistry and functional groups: Ensure that any stereochemistry or additional functional groups in the target molecule are correctly represented in the final product. Adjust the synthesis steps if needed to achieve the desired configuration.
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Tosylate Formation
Tosylates are formed by reacting an alcohol with tosyl chloride (TsCl) in the presence of a base. This reaction converts the alcohol into a better leaving group, the tosylate, which can facilitate nucleophilic substitution reactions. Understanding this transformation is crucial for synthesizing target molecules from alcohols.
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02:26
Formation of Enolates
Nucleophilic Substitution Reactions
Nucleophilic substitution reactions involve the replacement of a leaving group in a molecule with a nucleophile. There are two main mechanisms: SN1, which is unimolecular and involves carbocation formation, and SN2, which is bimolecular and involves a direct attack by the nucleophile. Recognizing which mechanism to apply is essential for predicting the outcome of the synthesis.
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Stereochemistry in Organic Synthesis
Stereochemistry refers to the spatial arrangement of atoms in molecules and is critical in organic synthesis, especially when creating chiral centers. The configuration of the starting materials and the reaction conditions can lead to different stereoisomers. Understanding how to control stereochemistry is vital for synthesizing specific target molecules with desired properties.
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Related Practice
Textbook Question
Predict the product of the following reactions.
(a)
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Textbook Question
A trifluoromethanesulfonate (triflate) can be used in a manner similar to tosylates. Which would you expect to be a better leaving group? Why?
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Textbook Question
Using an appropriate tosylate intermediate, synthesize the following molecules starting from the appropriate alcohol.
(a)
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Textbook Question
Predict the product of the following reactions.
(b)
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Textbook Question
Identify whether each of the following reactions proceed by an SN1, SN2, E1, or E2 mechanism.
(c)
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