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Chapter 11 Alcohols and Ethers

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Both alcohols and ethers can hydrogen bond to water and have similar solubilities in water ... with phosphorus tribromide, thionyl chloride or hydrogen halides ... – PowerPoint PPT presentation

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Title: Chapter 11 Alcohols and Ethers


1
Chapter 11Alcohols and Ethers
2
  • Nomenclature
  • Nomenclature of Alcohols (Sec. 4.3F)
  • Nomenclature of Ethers
  • Common Names
  • The groups attached to the oxygen are listed in
    alphabetical order
  • IUPAC
  • Ethers are named as having an alkoxyl substituent
    on the main chain

3
  • Cyclic ethers can be named using the prefix oxa-
  • Three-membered ring ethers can be called
    oxiranes Four-membered ring ethers can be
    called oxetanes

4
  • Physical Properties of Alcohols and Ethers
  • Ether boiling points are roughly comparable to
    hydrocarbons of the same molecular weight
  • Molecules of ethers cannot hydrogen bond to each
    other
  • Alcohols have considerably higher boiling points
  • Molecules of alcohols hydrogen bond to each other
  • Both alcohols and ethers can hydrogen bond to
    water and have similar solubilities in water
  • Diethyl ether and 1-butanol have solubilites of
    about 8 g per 100 mL in water

5
  • Synthesis of Alcohols from Alkenes
  • Acid-Catalyzed Hydration of Alkenes
  • This is a reversible reaction with Markovnikov
    regioselectivity
  • Oxymercuration-demercuration
  • This is a Markovnikov addition which occurs
    without rearrangement

6
  • Hydroboration-Oxidation
  • This addition reaction occurs with
    anti-Markovnikov regiochemistry and syn
    stereochemistry

7
  • Alcohols as Acids
  • Alcohols have acidities similar to water
  • Sterically hindered alcohols such as tert-butyl
    alcohol are less acidic (have higher pKa values)
  • Why? The conjugate base is not well solvated and
    so is not as stable
  • Alcohols are stronger acids than terminal alkynes
    and primary or secondary amines
  • An alkoxide can be prepared by the reaction of an
    alcohol with sodium or potassium metal

8
  • Conversion of Alcohols into Alkyl Halides
  • Hydroxyl groups are poor leaving groups, and as
    such, are often converted to alkyl halides when a
    good leaving group is needed
  • Three general methods exist for conversion of
    alcohols to alkyl halides, depending on the
    classification of the alcohol and the halogen
    desired
  • Reaction can occur with phosphorus tribromide,
    thionyl chloride or hydrogen halides

9
  • Alkyl Halides from the Reaction of Alcohols with
    Hydrogen Halides
  • The order of reactivity is as follows
  • Hydrogen halide HI gt HBr gt HCl gt HF
  • Type of alcohol 3o gt 2o gt 1o lt methyl
  • Mechanism of the Reaction of Alcohols with HX
  • SN1 mechanism for 3o, 2o, allylic and benzylic
    alcohols
  • These reactions are prone to carbocation
    rearrangements
  • In step 1 the hydroxyl is converted to a good
    leaving group
  • In step 2 the leaving group departs as a water
    molecule, leaving behind a carbocation

10
  • In step 3 the halide, a good nucleophile, reacts
    with the carbocation
  • Primary and methyl alcohols undergo substitution
    by an SN2 mechanism
  • Primary and secondary chlorides can only be made
    with the assistance of a Lewis acid such as zinc
    chloride

11
  • Alkyl Halides from the Reaction of Alcohols with
    PBr3 and SOCl2
  • These reagents only react with 1o and 2o alcohols
    in SN2 reactions
  • In each case the reagent converts the hydroxyl to
    an excellent leaving group
  • No rearrangements are seen
  • Reaction of phosphorous tribromide to give alkyl
    bromides

12
  • Reaction of thionyl chloride to give alkyl
    chlorides
  • Often an amine is added to react with HCl formed
    in the reaction

13
  • Tosylates, Mesylates, and Triflates Leaving
    Group Derivatives of Alcohols
  • The hydroxyl group of an alcohol can be converted
    to a good leaving group by conversion to a
    sulfonate ester
  • Sulfonyl chlorides are used to convert alcohols
    to sulfonate esters
  • Base is added to react with the HCl generated

14
  • A sulfonate ion (a weak base) is an excellent
    leaving group
  • If the alcohol hydroxyl group is at a stereogenic
    center then the overall reaction with the
    nucleophile proceeds with inversion of
    configuration
  • The reaction to form a sulfonate ester proceeds
    with retention of configuration
  • Triflate anion is such a good leaving group that
    even vinyl triflates can undergo SN1 reaction

15
  • Synthesis of Ethers
  • Ethers by Intermolecular Dehydration of Alcohol
  • Primary alcohols can dehydrate to ethers
  • This reaction occurs at lower temperature than
    the competing dehydration to an alkene
  • This method generally does not work with
    secondary or tertiary alcohols because
    elimination competes strongly
  • The mechanism is an SN2 reaction

16
  • Williamson Ether Synthesis
  • This is a good route for synthesis of
    unsymmetrical ethers
  • The alkyl halide (or alkyl sulfonate) should be
    primary to avoid E2 reaction
  • Substitution is favored over elimination at lower
    temperatures

17
  • Synthesis of Ethers by Alkoxymercuration-Demercura
    tion
  • An alcohol is the nucleophile (instead of the
    water nucleophile used in the analogous reaction
    to form alcohols from alkenes)
  • tert-Butyl Ethers by Alkylation of Alcohols
    Protecting Groups
  • This method is used to protect primary alcohols
  • The protecting group is removed using dilute acid

18
  • Silyl Ether Protecting Groups
  • Silyl ethers are widely used protecting groups
    for alcohols
  • The tert-butyl dimethysilyl (TBDMS) ether is
    common
  • The protecting group is introduced by reaction of
    the alcohol with the chlorosilane in the
    presence of an aromatic amine base such as
    imidazole or pyridine
  • The silyl ether protecting group is removed by
    treatment with fluoride ion (e.g. from tetrabutyl
    ammonium fluoride)

19
  • Reactions of Ethers
  • Acyclic ethers are generally unreactive, except
    for cleavage by very strong acids to form the
    corresponding alkyl halides
  • Dialkyl ethers undergo SN2 reaction to form 2
    equivalents of the alkyl bromide

20
  • Epoxides
  • Epoxides are three-membered ring cyclic ethers
  • These groups are also called oxiranes
  • Epoxides are usually formed by reaction of
    alkenes with peroxy acids
  • This process is called epoxidation and involves
    syn addition of oxygen

21
  • Magnesium monoperoxyphthalate (MMPP) is a common
    and safe peroxy acid for epoxidation
  • Epoxidation is stereospecfic
  • Epoxidation of cis-2-butene gives the meso cis
    oxirane
  • Epoxidation of trans-2-butene gives the racemic
    trans oxirane

22
  • Reaction of Epoxides
  • Epoxides are considerably more reactive than
    regular ethers
  • The three-membered ring is highly strained and
    therefore very reactive
  • Acid-catalyzed opening of an epoxide occurs by
    initial protonation of the epoxide oxygen, making
    the epoxide even more reactive
  • Acid-catalyzed hydrolysis of an epoxide leads to
    a 1,2-diol

23
  • In unsymmetrical epoxides, the nucleophile
    attacks primarily at the most substituted carbon
    of the epoxide

24
  • Base-catalyzed reaction with strong nucleophiles
    (e.g. an alkoxide or hydroxide) occurs by an SN2
    mechanism
  • The nucleophile attacks at the least sterically
    hindered carbon of the epoxide

25
  • Anti 1,2-Dihydroxylation of Alkenes via Epoxides
  • Opening of the following epoxide with water under
    acid catalyzed conditions gives the trans diol

26
  • Epoxide ring-opening is a stereospecific process

27
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