Aromatics ring oxygenation

Bromine trifluoride has found application in the conversion of (methylsulfanyl)thiocar-bonyl groups, bonded to carbon atoms in aromatic rings, oxygen atoms in alcohols and phenols, or to the phthalimide nitrogen atom, into trifluoromethyl groups.125... 

Furanes and benzofuranes in which an oxygenated ring is condensed into one or more aromatic rings. 

The organic chemical structural types believed to be characteristic of coals include complex polycyclic aromatic ring systems with connecting bridges and varied oxygen-, sulfur-, and nitrogen-containing functionalities. 

In order for the transferability of parameters to be a good description of the molecule, force fields use atom types. This means that a sp carbon will be described by different parameters than a. sp - carbon, and so on. Usually, atoms in aromatic rings are treated differently from sp atoms. Some force fields even parameterize atoms for specific functional groups. For example, the carbonyl oxygen in a carboxylic acid may be described by different parameters than the carbonyl oxygen in a ketone. 

Nitration of aromatic rings is possible by use of Pd(N03)2[356], Pd(OAc)2-NaN02[357], Pd(0Ac)2-N02[358], and Pd(0)-NO2[359], The nitration can be carried out fully catalytically by Pd(0Ac)2-N02 and oxygen. This reaction offers a promising new method of nitration without using mixed acids of HNO3 and H2SO4. 

In resonance terms the shorter carbon-oxygen bond distance in phenol is attrib uted to the partial double bond character that results from conjugation of the unshared electron pair of oxygen with the aromatic ring... 

Many of the properties of phenols reflect the polarization implied by the resonance description The hydroxyl oxygen is less basic and the hydroxyl proton more acidic in phenols than m alcohols Electrophiles attack the aromatic ring of phenols much faster than they attack benzene indicating that the ring especially at the positions ortho and para to the hydroxyl group is relatively electron rich... 

Phenolic compounds are commonplace natural products Figure 24 2 presents a sampling of some naturally occurring phenols Phenolic natural products can arise by a number of different biosynthetic pathways In animals aromatic rings are hydroxylated by way of arene oxide intermediates formed by the enzyme catalyzed reaction between an aromatic ring and molecular oxygen... 

In most of their reactions phenols behave as nucleophiles and the reagents that act on them are electrophiles Either the hydroxyl oxygen or the aromatic ring may be the site of nucleophilic reactivity m a phenol Reactions that take place on the ring lead to elec trophilic aromatic substitution Table 24 4 summarizes the behavior of phenols m reac tions of this type... 

The aromatic ring of a phenol like that of an arylamine is seen as an electron rich functional unit and is capable of a variety of reactions In some cases however it IS the hydroxyl oxygen that reacts instead An example of this kind of chemical reac tivity IS described m the following section... 

Acylatmg agents such as acyl chlorides and carboxylic acid anhydrides can react with phenols either at the aromatic ring (C acylation) or at the hydroxyl oxygen (O acylation)... 

Although a hydroxyl group strongly activates an aromatic ring toward electrophilic attack an oxyanion substituent is an even more powerful activator Electron delocaliza tion m phenoxide anion leads to increased electron density at the positions ortho and para to oxygen... 

In presence of—C=C— or of aromatic ring In presence of—C=0 bond In presence of two carbon-oxygen bonds In presence of two carbon-carbon double bonds Aryl-C=0... 

All laromatics. The aromatic ring is fairly inert toward attack by oxygen-centered radicals. Aromatic acids consisting of carboxyl groups substituted on aromatic rings are good candidates for production by LPO of alkylaromatics since thek k /k ratios are low. TerephthaUc acid [100-21 -0]... 

Conversion of Aromatic Rings to Nonaromatic Cyclic Structures. On treatment with oxidants such as chlorine, hypochlorite anion, chlorine dioxide, oxygen, hydrogen peroxide, and peroxy acids, the aromatic nuclei in lignin typically ate converted to o- and -quinoid stmctures and oxinane derivatives of quinols. Because of thein relatively high reactivity, these stmctures often appear as transient intermediates rather than as end products. Further reactions of the intermediates lead to the formation of catechol, hydroquinone, and mono- and dicarboxyhc acids. 

The aromatic ring of a phenoxy anion is the site of electrophilic addition, eg, in methylolation with formaldehyde (qv). The phenoxy anion is highly reactive to many oxidants such as oxygen, hydrogen peroxide, ozone, and peroxyacetic acid. Many of the chemical modification reactions of lignin utilizing its aromatic and phenoHc nature have been reviewed elsewhere (53). 

The aromatic rings of kraft lignins can be sulfonated to varying degrees with sodium sulfite at high temperatures (150—200°C) or sulfomethylated with formaldehyde and sulfite at low temperatures (<100° C). Oxidative sulfonation with oxygen and sulfite is also possible. 

Ultraviolet radiation causes cleavage of the aryl ether linkage (23). DMPPO undergoes oxidation when exposed to ultraviolet light and oxygen by direct attack on the aromatic ring to produce a variety of ring-cleaved and quinoidal stmctures (24). 

The alkylation desctibed in this article is the substitution of a hydrogen atom bonded to the carbon atom of a paraffin or aromatic ring by an alkyl group. The alkylations of nitrogen, oxygen, and sulfur are described in separate articles (see Amines Ethers). 

Doxepin [1668-19-5] (38), unlike other commercially available tricyclics, has an oxygen atom in the bridge between the two aromatic rings. It is marketed as a cis—trans mixture (1 5) of isomers, both of which are active. This close relative of amitriptyline (33) has both sedative and anxiolytic properties associated with its antidepressant profile. Maprotiline [10262-69-8] (39) and amoxapine [14028-44-5] (40) are pharmacologically, although not chemically, similar to the tricycHc secondary amines. Clomipramine [303-49-1] (41) has similar pharmacological and antidepressant efficacy. However, clomipramine is approved by the U.S. FDA only for the treatment of obsessive—compulsive disorder. Representative brands of tricycHc antidepressants marketed in the United States are Hsted in Table 2. 

The symbols f and f correspond to total fraction of and hybridi2ed carbon, respectively, f represents the fraction of carbon in aromatic rings f , the fraction in carbonyls, b > 165 ppm the aromatic fraction that is protonated the aromatic fraction that is nonprotonated f, the phenoHc or phenohc ether carbon, 6 = 150-165 ppm f, the alkylated aromatic carbon, 6 = 135-150 ppm , the aromatic bridgehead carbon f represents the fraction of CH or CH2 aUphatic carbon f, the CH or nonprotonated aUphatic carbon and f, the aUphatic carbon bound to oxygen, b — 50-90 ppm. 

---