Carbonates from phosgene reaction with alcohols

Carbonate and carbamate derivatives, prepared from the reaction of alcohols and amines with phosgene and /V-hydroxy-2-thiopyridone, provide the corresponding alkoxyl radicals and aminyl radicals respectively, via radical decarboxylation [71-81]. For example, photolytic treatment of carbamate (57) derived from 4-pentenylamine generates the corresponding 4-pentenylaminyl radical, as shown in eq. 8.24. Under neutral conditions in the presence of tert-BuSH, a direct reduction product (A) of 4-pentenylaminyl radical is formed, while, in acidic conditions, cyclized product (C), pyrrolidine, via 5-exo-trig manner from 4-pentenylaminyl radical is formed. Under the latter conditions, the real reactive species is an electrophilic 4-pentenylaminium radical which rapidly cyclized via 5-exo-trig manner. 

J. Fomiation of methylchloroformAte from phosgene and methyl alcohol by reaction with calcium carbonate. 

Phosgene reacts with alcohols or phenols (or their simple salt derivatives) to give two types of compound, chloroformates R0C(0)C1 Equation (4.7) and carbonates R0C(0)0R Equation (4.8), see Section 10.3.1. Carbonates are generally derived from the further reaction of the alcohol or phenol with the chloroformate. 

Ureas and Carbonates. Reagent (1) may be used as a direct replacement for the highly toxic Phosgene in reactions with alcohols and amines. Reaction of (1) with two equivalents of a primary aliphatic or aromatic amine at room temperature rapidly yields a symmetrical urea (eq 9). If only one equivalent of a primary amine is added to (1), then the imidazole-Al-carboxamide (4) is formed (eq 10). These compounds can dissociate into isocyanates and imidazole, even at room temperature, and distillation from the reaction mixture provides a useful synthesis of isocyanates (eq 10).7 Secondary amines react only at one side of (1) at room temperature, again giving the imidazole-Al-carboxamide of type... 

Dialkyl carbonates can be made from the reaction of alcohols with phosgene, a highly toxic gas. The second chlorine atom of phosgene increases the electrophilicity of the carbonyl carbon atom. As in the reaction of an alcohol with an acid chloride, a base is required to neutralize the HCl by-product. 

Carbonates ate manufactured by essentially the same method as chloroformates except that more alcohol is required in addition to longer reaction times and higher temperatures. The products are neutralized, washed, and distilled. Corrosion-resistant equipment similar to that described for the manufacture of chloroformates is requited. Diaryl carbonates are prepared from phosgene and two equivalents of the sodium phenolates or with phenols and various... 

A V -Carbonyldiimidazole (CDI) is prepared in a convenient and safe procedure from phosgene and imidazole as a non-toxic crystalline compound (m.p. 116-118 °C).[5],[6] It reacts almost quantitatively at room temperature or by short and moderate heating with an equimolar quantity of a carboxylic acid in tetrahydrofuran, chloroform, or similar inert solvents within a few minutes to give the corresponding carboxylic acid imidazolide, which is formed under release of carbon dioxide, together with one equivalent of readily separable and recyclable imidazole.Thus, this reaction leads under very mild conditions to the activation of a carboxylic acid appropriate for transacylation onto a nucleophile with an alcohol to an ester, with an amino compound to an amide or peptide, etc. 

The preparation of carbonates is mechanistically closely related to the synthesis of carbamates, and similar reagents can be used for this purpose (Table 14.10). Resin-bound alcohols can be directly converted into carbonates by treatment with a chloro-formate (see Experimental Procedure 14.2), in two steps by activation with phosgene or a synthetic equivalent thereof followed by reaction with an alcohol in the presence of a base, or by treatment of a resin-bound alcohol with carbon dioxide and an alkyl halide under basic reaction conditions [125]. Thiocarbonates can be prepared from... 

With respect to the synthesis from amines, C02 and alkyl halides, the synthesis of carbamates from amines, C02 and alcohols (Equation 6.10) is not only a phosgene-free, but also a halogen-free process. Moreover, water forms as the only reaction coproduct. Whilst these features make the route very attractive from the point of view of environmental sustainability, unfortunately the reaction suffers from both thermodynamic and kinetics limitations. Kinetic impediments make necessary the use of a suitable catalyst which, moreover, must be water-tolerant in order to avoid deactivation by cogenerated H20. Several strategies have been explored to overcome these restraints, based mainly on the use of alcohols in a dehydrated form (for instance, as ortho esters or ortho carbonates) [63], or on the use of dehydrating agents [64, 65]. 

Other types of polycarbonates have also been made using a very different approach from that involving bisphenol A and related compounds. For example, the reaction between phosgene and allyl alcohol (CH2=CHCH2OH) produces a monomer with carbon-carbon double bonds at both ends of the molecule that can be used for polymerization. Interestingly enough, the polycarbonate produced by this process has very different physical properties from the traditional bisphenol A polymer. The allyl polymer is a clear, transparent, flexible plastic whose primary use is in the production of eyeglass lenses. 

PROBLEM 18.13 Dialkyl carbonates can be made from the reaction of phosgene with alcohols. These carbonates are converted into tertiary alcohols with three identical R groups on reaction with three equivalents of a Grignard reagent or an organolithium reagent. Provide mechanisms for the formation of carbonates and tertiary alcohols in these reactions. 

Reactions with Carboxylic Acids, Alcohols, and Amines. Phosgene reacts with carboxylic acids to give anhydrides, with liberation of carbon dioxide. This has been used to activate acids to attack from nucleophiles, e.g. in esterification, lactonization, and thiolation. For example, acids can be protected as 3-butenyl esters using phosgene and Pyridine, followed by addition of 3-buten-l-ol (eq 1). 

Isothioureas can be prepared on insoluble supports by S-alkylation or S-arylation of thioureas (Entry 7, Table 14.6). Further methods for the preparation of isothioureas on insoluble supports include the N-alkylation of polystyrene-bound, A/,/V -di(alkoxy-carbonyl)isothioureas with aliphatic alcohols by Mitsunobu reaction (Entry 7, Table 14.6) and the addition of thiols to resin-bound carbodiimides [7]. Resin-bound dithio-carbamates, which can easily be prepared from Merrifield resin, carbon disulfide, and amines [76], react with phosgene to yield chlorothioformamidines, which can be converted into isothioureas by treatment with amines (Entry 8, Table 14.6). The conversion of support-bound a-amino acids into thioureas can be accompanied by the release of thiohydantoins into solution (see Section 15.9). The rate of this cyclization depends, however, on the type of linker used and on the nucleophilicity of the intermediate thiourea. 

The starting compound was also condensed with an aldehyde in 82-84% yield with more than 98% ee. A corresponding amide from an fi unsaturated acid underwent the Diels-Alder reaction in 86-90% yield with more than 99% ee. The original amino alcohol was probably treated with phosgene to close the oxazolidone ring.63 The less toxic dimethyl carbonate might be a suitable replacement for the phosgene. The use of another chiral auxiliary for alkylation is shown in 10.30.64... 

The polycondensation of a diol and the diester of a dicarboxylic acid (e.g., the dimethyl ester) can be carried out in the melt at a considerably lower temperature than for the corresponding reaction of the free acid. Under the influence of acidic or basic catalysts a transesterification occurs with the elimination of the readily volatile alcohol (see Example 4.3). Instead of diesters of carboxylic acids one can also use their dicarboxylic acid chlorides, for example, in the synthesis of high-melting aromatic polyesters from terephthaloyl dichloride and bisphenols. The commercially very important polycarbonates are obtained from bisphenols and phosgene, although the use of diphenyl carbonate as an alternative component is of increasing interest (see Example 4.4). Instead of free acids, cyclic carboxylic... 

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