Chloroformic acid esters aryl chloroformates

Table 2 contains the characteristics of the amic ester-aryl ether copolymers including coblock type, composition, and intrinsic viscosity. Three series of copolymers were prepared in which the aryl ether phenylquinoxaline [44], aryl ether benzoxazole [47], or aryl ether ether ketone oligomers [57-59] were co-re-acted with various compositions of ODA and PMDA diethyl ester diacyl chloride samples (2a-k). The aryl ether compositions varied from approximately 20 to 50 wt% (denoted 2a-d) so as to vary the structure of the microphase-separated morphology of the copolymer. The composition of aryl ether coblock in the copolymers, as determined by NMR, was similar to that calculated from the charge of the aryl ether coblock (Table 2). The viscosity measurements, also shown in Table 2, were high and comparable to that of a high molecular weight poly(amic ethyl ester) homopolymer. In some cases, a chloroform solvent rinse was required to remove aryl ether homopolymer contamination. It should also be pointed out that both the powder and solution forms of the poly(amic ethyl ester) copolymers are stable and do not undergo transamidization reactions or viscosity loss with time, unlike their poly(amic acid) analogs.

Attempts to apply the thermal decarboxylation reaction in the liquid phase to aromatic halofor-mic acid esters have shown that their reaction is different from that ol the aliphatic haloformates. It was found that evolution of carbon dioxide occurs, but only high boiling products could be isolated.136 On heating in the presence of aromatics and Lewis acids, aryl chloroformates do not react to give chlorinated aromatics with concomitant decarboxylation, but undergo a Friedel-Crafts reaction to give phenyl benzoates.137 Under similar conditions phenyl fluoroformate undergoes only polymerization and carbonate formation.137... 

Methyl, ethyl, benzyl, benzhydryl, p-nitrobenzyl, p-methoxy-benzyl, 4-picolyl, j3j -trichloroethyl, j3-methylthioethyl, /J-p-toluenesulphonylethyl, and -p-nitrophenylthioethyl esters may be prepared directly from the acid and alcohol. TTie most usual method [4, 5] consists of heating the acid and an excess of the alcohol with an acid catalyst (e.g., Fischer-Speier, hydrochloric or sulphuric acid). The extent of reaction is improved if the water formed is removed by azeotropic distillation with an inert solvent (benzene, carbon tetrachloride, or chloroform). Considerable variation is possible in the natvire of the acid catalyst thus phosphoric acid [6], aryl sulphonic acids [7, 8, 9], alkyl sulphates [10], and acidic ion-exchange resins [11] may be employed. Removal of the water by azeotropic distillation during the formation of methyl esters is difficult and Brown and Lovette [12] introduced the novel reagent acetone dimethyl acetal (7) for the direct formation of methyl esters. In the presence of a trace of methanol and an acid catalyst the reagent acts as a scavenger of water formed by esterification and liberates further methanol for reaction. 

Acylation. Aryl chloroformates are good acylating agents, reacting with aromatic hydrocarbons under Eriedel-Crafts conditions to give the expected aryl esters of the aromatic acid (38). 

Acid chlorides are used for the quantitative deterrnination of hydroxyl groups and for acylation of sugars. Industrial appHcations include the formation of the alkyl or aryl carbonates from phosgene (see Carbonic and chloroformic esters) and phosphate esters such as triethyl, triphenyl, tricresyl, and tritolyl phosphates from phosphoms oxychloride. 

C-Activated esters 6 are prepared by reacting hydrazides 4 with aryl chloroformates 5 (X=Q) or carbonic diesters 5 (X=OAr),M whereas N-activated esters 9 are obtained by reaction of the free amino group of N-terminal amino acid 7 or azaamino acid residues with the same reagents. 

Alcohols and phenols can be attached to support-bound alcohol linkers as carbonates [467,665,666], although few examples of this have been reported. For the preparation of carbonates, the support-bound alcohol needs to be converted into a reactive carbonic acid derivative by reaction with phosgene or a synthetic equivalent thereof, e.g. disuccinimidyl carbonate [665], carbonyl diimidazole [157], or 4-nitrophenyl chloro-formate [467] (see Section 14.7). The best results are usually obtained with support-bound chloroformates. The resulting intermediate is then treated with an alcohol and a base (DIPEA, DMAP, or DBU), which furnishes the unsymmetrical carbonate. Carbonates are generally more resistant towards nucleophilic cleavage than esters, but are less stable than carbamates. Aryl carbonates are easily cleaved by nucleophiles and are therefore of limited utility as linkers for phenols. 

Other methods that can be used to prepare thiol esters from carboxylic acids include the use of aryl thiocyanates,12 thiopyridyl chloroformate,13 2-fIuoro- V-methylpyridinium tosylate,14 1-hydroxybenzotriazole, 5 and boron thiolate.16 Direct conversion of 0-esters to 5-esters can also be effected via aluminum and boron reagents.17 However, the applicability of these 1217 and other more recent methods18 to the selective thiol ester formation discussed above has not been clearly defined. 

Primary and secondary amides and thioamides react with alkyl chlorofoimates with loss of CO2 or COS, forming iminium chlorides (82 equation 52). In some cases this method is complementary to the Pinner imido ester hydrochloride synthesis. The iminium salt (83 Scheme 6) formed by action of ethyl chloroformate on DMF is labile and decomposes rapidly to ethyl chloride. If the reaction is performed in the presence of NaBp4, the iminium salt (85) is isolable. Aryl chlorofoimates react in the same fashion with DMF or DMA, but in these cases the aryloxymethyleneiminium compounds are fairly stable, so this reaction is an important method for the preparation of compounds of this type. - Succinic acid monoamides, phthalic acid monoamides and related compounds are cyclized to iminium salts (86 equation 53) by treatment with acetic anhydride and HC104. ° With the aid of trifluoromethanesulfonic anhydride lactams and amides can be converted to dication ether salts (87) and (88 Scheme 7).22i.222... 

Alkyl esters of phosphonous and phosphinous acid also react readily y with carbon tetrachloride, while analogous aryl esters, e.g., EtP(OPh)2, are resistant even at 160° (152,173). The reaction of bromotrichloro-methane with triethyl phosphite, which occurs smoothly at 80° to furnish dialkyl trichloromethylphosphonate in excellent yield (99%), is light catalyzed. Chloroform is unchanged in the presence of triethyl phosphite (98,156) even under drastic conditions, and diethyl dichloro-methylphosphonate is not produced unless a free radical initiator is present (118). 

A simple modification to the general Michaelis-Arbuzov procedure, in which the phosphorus(III) esters 390 (R = OR, alkyl, or aryl) and derivatives of chloroformic acid... 

The synthesis of 86 commenced with oxazole carboxylic acid 87. Base-catalyzed lithiation and coupling with isatin 88 followed by methyl ester formation and Boc deprotection provided tertiary alcohol 89. A second coupling of the amine 89 with carboxylic acid 90 followed by chlorination afforded chloride 91. Treatment of 91 with TBAF gave a 1 1 mixture of O-aryl ether 92 (CIO) in excellent yield. Refluxing 92 in chloroform resulted in the formation of 93 (70%, with 30% of the isomer), which was subjected to a three-step reaction sequence to furnish intermediate 86 (Scheme 16). 

Reactions. BSF is readily acylated with acid chlorides and chloroformate esters to provide Al-TMS-iV-formylamides and carbamates, respectively, which readily undergo protodesilylation (eq 17). BSF reacts with 2 equiv of an alkyl or aryl isocyanate to give l,3,5-triazine-2,4-diones in good to excellent yields (eq 18). In the case of orthocarboxamides, iV-formylform-amidines can be obtained (eq 19) ... 

Ethyl chloroformate/triethylamine Carboxylic acid aryl esters from carboxylic acids and phenols... 

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