Chapter 21 Phenols and Aryl Halides: Nucleophilic Aromatic Substitution



Structure and Nomenclature of Phenols



Phenols have hydroxyl groups bonded directly to a benzene ring



Naphthols and phenanthrols have a hydroxyl group bonded to a polycyclic benzenoid ring

Chapter 21 2



Nomenclature of Phenols



Phenol is the parent name for the family of hydroxybenzenes



Methylphenols are called cresols

Chapter 21 3



Synthesis of Phenols



Laboratory Synthesis



Phenols can be made by hydrolysis of arenediazonium salts

Chapter 21 4



Industrial Syntheses



1. Hydrolysis of Chlorobenzene (Dow Process)

 

Chlorobenzene is heated with sodium hydroxide under high pressure The reaction probably proceeds through a benzyne intermediate (Section 21.11B)



2. Alkali Fusion of Sodium Benzenesulfonate



Sodium benzenesulfonate is melted with sodium hydroxide

Chapter 21 5



3. From Cumene Hydroperoxide



Benzene and propene are the starting materials for a three-step sequence that produces phenol and acetone



Most industrially synthesized phenol is made by this method



The first reaction is a Friedel-Crafts alkylation

Chapter 21 6



The second reaction is a radical chain reaction with a 3 o benzylic radical as the chain carrier

Chapter 21 7



The third reaction is a hydrolytic rearrangement (similar to a carbocation rearrangement) that produces acetone and phenol



A phenyl group migrates to a cationic oxygen group

Chapter 21 8



Reactions of Phenols as Acids



Strength of Phenols as Acids



Phenols are much stronger acids than alcohols

Chapter 21 9



Phenol is much more acidic than cyclohexanol



Experimental results show that the oxygen of a phenol is more positive and this makes the attached hydrogen more acidic

 

The oxygen of phenol is more positive because it is attached to an electronegative sp 2 carbon of the benzene ring Resonance contributors to the phenol molecule also make the oxygen more positive

Chapter 21 10



Distinguishing and Separating Phenols from Alcohols and Carboxylic Acids



Phenols are soluble in aqueous sodium hydroxide because of their relatively high acidity

 

Most alcohols are not soluble in aqueous sodium hydroxide A water-insoluble alcohol can be separated from a phenol by extracting the phenol into aqueous sodium hydroxide



Phenols are not acidic enough to be soluble in aqueous sodium bicarbonate (NaHCO 3 )



Carboxylic acids are soluble in aqueous sodium bicarbonate



Carboxylic acids can be separated from phenols by extracting the carboxylic acid into aqueous sodium bicarbonate

Chapter 21 11



Other Reactions of the O-H Group of Phenols



Phenols can be acylated with acid chlorides and anhydrides

Chapter 21 12



Phenols in the Williamson Ether Synthesis



Phenoxides (phenol anions) react with primary alkyl halides to form ethers by an S N 2 mechanism

Chapter 21 13



Cleavage of Alkyl Aryl Ethers



Reaction of alkyl aryl ethers with HI or HBr leads to an alkyl halide and a phenol



Recall that when a dialkyl ether is reacted, two alkyl halides are produced

Chapter 21 14



Reaction of the Benzene Ring of Phenols



Bromination



The hydroxyl group is a powerful ortho, meta director and usually the tribromide is obtained



Monobromination can be achieved in the presence of carbon disulfide at low temperature



Nitration



Nitration produces

o

- and

p

-nitrophenol



Low yields occur because of competing oxidation of the ring

Chapter 21 15



Sulfonation



Sulfonation gives mainly the the ortho (kinetic) product at low temperature and the para (thermodynamic) product at high temperature

Chapter 21 16



The Kolbe Reaction



Carbon dioxide is the electrophile for an electrophilic aromatic substitution with phenoxide anion

  

The phenoxide anion reacts as an enolate The initial keto intermediate undergoes tautomerization to the phenol product Kolbe reaction of sodium phenoxide results in salicyclic acid, a synthetic precursor to acetylsalicylic acid (aspirin)

Chapter 21 17



The Claisen Rearrangement



Allyl phenyl ethers undergo a rearrangement upon heating that yields an allyl phenol



The process is intramolecular; the allyl group migrates to the aromatic ring as the ether functional group becomes a ketone



The unstable keto intermediate undergoes keto-enol tautomerization to give the phenol group



The reaction is concerted,

i.e

., bond making and bonding breaking occur at the same time

Chapter 21 18



Allyl vinyl ethers also undergo Claisen rearrangement when heated



The product is a

g

-unsaturated carbonyl compound



The

Cope rearrangement

is a similar reaction



Both the Claisen and Cope rearrangements involve reactants that have two double bonds separated by three single bonds

Chapter 21 19



The transition state for the Claisen and Cope rearrangements involves a cycle of six orbitals and six electrons, suggesting aromatic character



This type of reaction is called

pericyclic



The Diels-Alder reaction is another example of a pericyclic reaction

Chapter 21 20



Quinones



Hydroquinone is oxidized to

p

-benzoquinone by mild oxidizing agents



Formally this results in removal of a pair of electrons and two protons from hydroquinone



This reaction is reversible



Every living cell has ubiquinones (Coenzymes Q) in the inner mitochondrial membrane



These compounds serve to transport electrons between substrates in enzyme catalyzed oxidation-reduction reactions

Chapter 21 21



Aryl Halides and Nucleophilic Aromatic Substitution



Simple aryl and vinyl halides do not undergo nucleophilic substitution



Back-side attack required for S N 2 reaction is blocked in aryl halides

Chapter 21 22



S N 2 reaction also doesn’t occur in aryl (and vinyl halides) because the carbon-halide bond is shorter and stronger than in alkyl halides



Bonds to

sp

2 -hybridized carbons are shorter, and therefore stronger, than to

sp

3 -hybridized carbons



Resonance gives the carbon-halogen bond some double bond character

Chapter 21 23



Nucleophilic Aromatic Substitution by Addition Elimination: The S N Ar Mechanism



Nucleophilic substitution can occur on benzene rings when strong electron-withdrawing groups are ortho or para to the halogen atom



The more electron-withdrawing groups on the ring, the lower the temperature required for the reaction to proceed

Chapter 21 24



The reaction occurs through an addition-elimination mechanism



A Meisenheimer complex, which is a delocalized carbanion, is an intermediate



The mechanism is called nucleophilic aromatic substitution (S N Ar)



The carbanion is stabilized by electron-withdrawing groups in the ortho and para positions

Chapter 21 25



Nucleophilic Aromatic Substitution through an Elimination-Addition Mechanism: Benzyne



Under forcing conditions, chlorobenzene can undergo an apparent nucleophilic substitution with hydroxide



Bromobenzene can react with the powerful base amide

Chapter 21 26



The reaction proceeds by an elimination-addition mechanism through the intermediacy of a benzyne (benzene containing a triple bond)

Chapter 21 27



A calculated electrostatic potential map of benzyne shows added electron density at the site of the benzyne

p

bond



The additional

p

bond of benzyne is in the same plane as the ring



When chlorobenzene labeled at the carbon bearing chlorine reacts with potassium amide, the label is divided equally between the C-1 and C-2 positions of the product



This is strong evidence for an elimination-addition mechanism and against a straightforward S N 2 mechanism

Chapter 21 28



Benzyne can be generated from anthranilic acid by diazotization

 

The resulting compound spontaneously loses CO 2 and N 2 to yield benzyne The benzyne can then be trapped

in situ

using a Diels-Alder reaction



Phenylation



Acetoacetic esters and malonic esters can be phenylated by benzyne generated

in situ

from bromobenzene

Chapter 21 29



Spectroscopic Analysis of Phenols and Aryl Halides



Infrared Spectra



Phenols show O-H stretching in the 3400-3600 cm -1 region



1 H NMR



The position of the hydroxyl proton of phenols depends on concentration



In phenol itself the O-H proton is at

d

solution 2.55 for pure phenol and at

d

5.63 for a 1%



Phenol protons disappear from the spectrum when D 2 O is added



The aromatic protons of phenols and aryl halides occur in the

d

9 region 7-



13 C NMR



The carbon atoms of phenols and aryl halides appear in the region

d

135-170

Chapter 21 30