Isocyanates carbonylation

The structure of the acetalic copolymer indicates that the carbonyl group of phenyl isocyanate is involved in the copolymerisation. This is connected with the presence of the phenyl substituent at the isocyanate nitrogen atom. Thus, alternating coordinations of comonomers via oxygen atoms of the isocyanate carbonyl group and the oxirane, followed by coordinating comonomer enchainments, have been postulated to take place throughout the copolymerisation [266]. 

Fig. 10. FT-IR absorption spectra for blocked (initial) and deblocked (final) isophorone diisocyanate. 2256 cm unblocked isocyanate carbonyl 1738 cm" = blocked isocyanal e carbonyl 1503 cm" = blocked isocyanate N-H 1446 cm" = aliphatic reference peak.

Fig. 11. Normalized FT-IR absorbance b nds for the blocked isocyanate carbonyl (1738 cm" ) an< the unblocked isocyanate functionality (2256 cm" ).

N-Carbonylsulfamoyl chloride s. Ghlorosulfonyl isocyanate Carbonyl sulfide s. Carbon oxide sulfide Carboraffin 23,142 Carbostyrils... 

The general theory behind the process is that the hypohalite will convert the amide to a haloamide. This then spontaneously changes to the isocyanate when heated and decomposes to the amine from the water present. In effect, all that happens is that a Carbonyl (CO) group is stripped off the starting amide to yield the corresponding amine. Yields pre- purification are around 80%, post-purification average around 65%. Certain uses of the result-... 

Reductive carbonylation of nitro compounds is catalyzed by various Pd catalysts. Phenyl isocyanate (93) is produced by the PdCl2-catalyzed reductive carbonylation (deoxygenation) of nitrobenzene with CO, probably via nitrene formation. Extensive studies have been carried out to develop the phosgene-free commercial process for phenyl isocyanate production from nitroben-zene[76]. Effects of various additives such as phenanthroline have been stu-died[77-79]. The co-catalysts of montmorillonite-bipyridylpalladium acetate and Ru3(CO) 2 are used for the reductive carbonylation oLnitroarenes[80,81]. Extensive studies on the reaction in alcohol to form the A -phenylurethane 94 have also been carried out[82-87]. Reaction of nitrobenzene with CO in the presence of aniline affords diphenylurea (95)[88]. 

Hydroxy-THISs add regioselectively to the C=N bonds of isocyanates or isothiocyanates. The initially formed cycloadducts eliminate carbonyl sulfide with formation of 4-hydroxy- or 4-mercaptoimidazolium hydroxide inner salts (21) (Scheme 21). 4-Hydroxyimidazolium hydroxide... 

Both dimethyl carbonate [616-38-6] and diphenyl carbonate [102-09-0] have been used, in place of carbon monoxide, as reagents for the conversion of amines into isocyanates via this route (28,29). Alternatively, aniline [62-53-3] toluene diamines (I JJA), and methylene dianilines (MDA) have also been used as starting materials in the carbonylations to provide a wide variety of isocyanate monomers. 

Attempts have been made to develop methods for the production of aromatic isocyanates without the use of phosgene. None of these processes is currently in commercial use. Processes based on the reaction of carbon monoxide with aromatic nitro compounds have been examined extensively (23,27,76). The reductive carbonylation of 2,4-dinitrotoluene [121 -14-2] to toluene 2,4-diaLkylcarbamates is reported to occur in high yield at reaction temperatures of 140—180°C under 6900 kPa (1000 psi) of carbon monoxide. The resultant carbamate product distribution is noted to be a strong function of the alcohol used. Mitsui-Toatsu and Arco have disclosed a two-step reductive carbonylation process based on a cost effective selenium catalyst (22,23). 

Pyrolysis approaches can also be used to prepare substituted isocyanates which caimot be prepared using other methods. For example, A[,A[(A[ -trichlorocyanuric acid [87-90-1] thermally dissociates to yield chloroisocyanate [13858-09-8] and carbonyl diisocyanate [6498-10-8]. The carbonyl isocyanate is unstable and polymerizes (8,94). Table 3 Hsts specialty isocyanates. 

The photochemical addition of azirines to the carbonyl group of aldehydes, ketones, and esters is also completely regiospecific (77H(6)143). Besides the formation of the isomeric oxazolines (50) from (39) and ethyl cyanoformate, there is also formed the imidazole (51) from addition to C=N in the expected regioselective manner. Thioesters lead to thiazolines (52), while isocyanates and ketenes produce heterocycles (53). 

Acetylene works Acrylates works Aldehyde works Aluminum works Amines works Ammonia works Anhydride works Arsenic works Asbestos works Benzene works Beryllium works Bisulfate works Bromine works Cadmium works Carbon disulfide works Carbonyl works Caustic soda works Cement works Ceramic works Chemical fertilizer works Chlorine works Chromium works Copper works Di-isocyanate works Electricity works Fiber works Fluorine works Gas liquor works Gas and coke works Hydrochloric acid works Hydrofluoric acid works Hydrogen cyanide works Incineration works Iron works and steel works... 

N-benzylaniline with phosgene, and then with sodium azide to produce carbonyl azide 52. On heating, nitrogen is evolved and a separable mixture of nitrene insertion product 53 and the desired ketoindazole 54 results. The latter reaction appears to be a Curtius-type rearrangement to produce an N-isocyanate (54a), which then cyclizes. Alkylation of the enol of 54... 

Carbamate, RNHCOOR, produced from carbonylation pathways can be selectively converted to isocyanate (1.4). Carbonylation pathways offer a number of advantages (i) the environmentally benign nature of the reactants, (ii) the high selectivity of the reaction processes, (iii) the stability and low toxicity of carbamate products and (iv) the wide range of applications of carbamate as chemical feedstock. 

Fig. 11) would likely proceed by different mechanisms. Protonation of the diol (IV, Fig. 12) derived from theobromine would lead to ring opening at the C6— Cs position giving an imidazole isocyanate (XVI, Fig. 12). This could readily form XVII which after hydrolysis and loss of C02 would give dimethyl-allantoin (XVIII). On the other hand, the uric acid diol derived from caffeine (X, Fig. 12) cannot fragment by this mechanism. Accordingly, either or both of the processes could Occur via the form of the diol hydrated at the C6 carbonyl group (XIX, Fig. 12) which could readily lose C02 to give XX followed by rearrangement to trimethylallantoin (XXI).

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