Diaryl ether condensation

Ullman reaction The synthesis of diaryls by the condensation of aromatic halides with themselves or other aromatic halides, with the concomitant removal of halogens by a metal, e.g. copper powder thus bromobenzene gives diphenyl. The reaction may be extended to the preparation of diaryl ethers and diaryl thio-ethers by coupling a metal phenolate with an aryl halide. 

Reaction of bis (sulfonyl chloride)s with diaryl ether produces polyethersulfones. For example, condensation of diphenyl ether with the disulfonylchloride of diphenyl ether yields polyethersulfone (5) ... 

Hardwoods appear to have a much higher content of such aryl-glycerol-p,y-diaryl ethers because of the more restricted possibilities for condensations in the aromatic ring of sinapyl-type units owing to their two methoxyl groups. This is reflected in the greater susceptibility of hardwood lignins to mild hydrolysis (see Section I). 

Phenolic compounds can be condensed forming aryl-aryl and aryl-oxygen-aryl (ether linkages) bonds to yield diaryl and diaryl ether polymers (59). These are in many ways similar to natural humic acids, confirming earlier research by others (60-62) that humic acids are formed from the copolymerization of phenolic compounds with amino acids, peptides, and amino sugars. 

Vttmann diaryl ether synthesis. This copper(I) derivative is recommended as the condensing reagent in the Ullmann synthesis of diaryl ethers from phenols and bromoarenes in refluxing pyridine (equation I). 

Cuprous oxide was found superior to other copper species as reagent and catalyst for (he preparation of diaryl ethers by a modified Ullmann condensation, ... 

The standard methods for the synthesis of xanthones are via the benzophe-none 17 and diaryl ether intermediates 18 (Fig. 7). The intermediate ben-zophenone derivatives 17 can be obtained by condensation between an ortho-oxygenated benzoic acid and an activated phenol, in the presence of phosphorus oxychloride and zinc chloride (a) [44]. This intermediate is also accessible through condensation by the Friedel-Crafts acylation of appropriately substituted benzoyl chlorides with phenolic derivatives (b) [45]. Then the oxidative or dehydrative processes cause the cyclization of 2,2 -di-oxygenated ben-zophenone to xanthone (c) [46]. 

The other method can be carried out via a suitable diaryl ether intermediate 18, which can be obtained from the condensation of a phenol and an... 

As base. Numerous reactions that are initiated by deprotonation have been conducted with KF-AI2O3. These include the synthesis of diaryl ethers, amines, and sulfides by nucleophilic aromatic substitutions, AJ-alkylation of 2,4-dinitrophenyl-hydrazones, condensation of 3-phenylisoxazol-5-one with aldehydes, and ring closure of /V-(w-chloroalkyl) carboxamides to afford 1,3-oxazolines and 1,3-oxazines. ... 

Various synthetic approaches have been demonstrated for the synthesis of PAEs since early days [35 0], PAEs were synthesized by Ullmann condensation between bisphenols and aryl fcis-halide monomers using Cu(I) salt/pyridine as catalyst [36], General Electric developed the first commercially successful PAE poly(2,6-dimethyl phenylene oxide) (PPO) [38], It was prepared by oxidative coupling of 2,6-dimethyI phenol. However, this process has its own restrictions, because it does not allow much structural variation or inclusion of any electron-withdrawing group into the polymer main chain. First attempts to synthesize polysulfones (PSF) were successfully done by Friedel-Crafts sulfonylation reaction of arylenedisulfonyl chlorides, for example, diphenyl ether-4,4 -disulfonyl chloride with diaryl ethers, for example, diphenyl ether, or by self-condensation of 4-phenoxy benzene sulfonyl chloride in the presence of FeCls [41], Whereas the former reaction involves side reactions (sulfonylation not only in the para- but also in the ort/io-position), the latter produces only the desired linear all-para products. 

Polyetherimides are a new family of condensation polymers. The key reaction step in each of their synthetic sequences is an aromatic nitro-displacement reaction which produces the diaryl ether linkages in high yield. Physical properties can be varied over a wide range depending on the choices of bis-phenol, diamine, and positional isomer incorporated into the backbone of the polymer. Our study of these materials has led to the commercial introduction of ULTEM Resin as the first in a series of new high performance engineering thermoplastics. 

Elix, Musidlak, Sala and Sargent 128) have reported a novel synthetic route to xanthones which used an Ullmann reaction to produce a diaryl ether and its subsequent condensation to yield the xanthones (route C). This route is exemplified by the synthesis of thiophaninic acid (136) (Scheme 16). 

Polyarylether Ketones. The aromatic polyether ketones are tme thermoplastics. Although several are commercially available, two resins in particular, poly ether ether ketone [31694-16-3] (PEEK) from ICI and poly ether ketone ketone (PEKK) from Du Pont, have received most of the attention. PEEK was first synthesized in 1981 (20) and has been well studied it is the subject of numerous papers because of its potential use in high performance aircraft. Tough, semicrystalline PEEK is prepared by the condensation of bis(4-fiuorophenyl) ketone with the potassium salt of bis(4-hydroxyphenyl) ketone in a diaryl sulfone solvent, such as diphenyl sulfone. The choice of solvent is critical other solvents, such as Hquid HE, promote the reaction but lead to premature low molecular-weight crystals, which do not exhibit sufficient toughness (21). 

Patents of Dow Chemicals first described 9,9-diaryl-substituted PF homopolymers 204 and 205 by Yamamoto polymerization of the corresponding 2,7-dibromo monomers [272], although the methods for monomer preparation were not described. For unsubstituted fluorenone, a convenient method for its conversion into 9,9-(4-hydroxyphenyl)-[307-309] and 9,9-(4-alkoxyphenyl)fluorenes [310] was reported previously, which included condensation of fluorenone with phenol or its ethers in acidic conditions (dry HC1 [308,309] or H2SO4 [307,311]) in the presence of (3-mcrcaptopropionic or mercaptoacetic acids. Both polymers 204 and 205 showed similar Mn 21,000 with PDI of 1.48 and 1.75, respectively, and spectral data typical for PF (205 Aabs = 389 (r 50,000 //(mol cm) APL = 417, 439, and 473 mn (THF)) (Chart 2.48). 

Alkyl- or aryl-dibenzothiophenes are conveniently prepared from the 2-arylthio-cyclohexanones, which are readily cyclized and dehydrogenated to yield the respective 1-, 2-, 3- or 4-substituted dibenzothiophenes (382 equation 9 Section 3.15.2.3.2). More complex polycyclic systems are available, using suitable aryenethiols, such as naph-thalenethiols, and 2-bromo-l-tetralone to synthesize the appropriate 2-arylthio ketones. Diaryl sulfides can be converted to dibenzothiophene derivatives in satisfactory yields by photolysis in the presence of iodine (equation 10) (75S532). Several alkyldibenzothiophenes with substituents in the 2- and/or 3-positions were prepared in satisfactory yield by the condensation of dichloromethyl methyl ether with substituted allylbenzo[6]thiophenes (equation 11) (74JCS(P1)1744). 

Quinolyl)pyrazoIo[3,4-i7]pyridazincs were prepared by cyclocondensation reactions of an anilino-pyrazole acid with acetaldehyde <02JHC869>. Cyclopentadienyl-derived y-diketones and arylhydrazines condensed to 4-(l,4-diaryl-2//-cyclopent[d]pyridazin-2-yl)-benzenesulfonamides <02H(57)2383>. Sulfonated polyfphthalazinone ether sulfone)s 37 were prepared by polycondensation of 4-(4-hydroxyphenyl)phthalazinone 36 with various ratios of disodium 5,5 -sulfonylbis(2-fluorobenzenesulfonate) and bis(4-fluorophenyl)sulfone <02P5335>. 

Diaryl tellurium dichlorides can be obtained by condensation of aromatic hydrocarbons with tellurium tetrachloride. Refluxing solutions of the tellurium dichlorides in bis-[methoxyethyl] ether in the presence of Raney nickel2 3 or in acetic acid/sodium acetate in the presence of palladium(II) chloride4 produces biaryls in yields ranging from 10 to 91%. 

Alkyl- and 4-aryl-4/7-l,3,5-thiadiazines (224) are readily accessible by a one-pot BFs-etherate-catalyzed condensation of an aldehyde, a carbonitrile and a thioamide <758266,81JAP(K)5657779>. The reaction is also successful with dialkyl ketones but not with diaryl ketones <77S476>. A mechanistic rationale involving initial addition of the thioamide to the aldehyde (or ketone) followed by 1,4-polar cycloaddition of the derived cation (223) to the nitrile is proposed (Scheme 37) <75S266>. 

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