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Phosgene and Phosgene Substitutes

Eckert's Cartridges for Safe Phosgenations

Schematic representation of phosgene and common phosgene substitues

Because phosgene is a poisonous gas, many attempts have been made to substitute it with phosgene equivalents. The most common substitutes are diphosgene (DP; 15,159-9), triphosgene (TP; 33,075-2), carbonyl diimidazole (CDI; 11,553-3), disuccinimidyl carbonate (DSC; 22,582-7). Of these substitutes, only DP and TP behave like phosgene in all four basic transformations (introduction of carbonyls, chloro substituents, chlorocarbonyls, and dehydration products). CDI is also very well-known, particularly in carbonylation reactions. A comparison of physical data of phosgene and its substitutes is in (Table 1).

Table 1.Physical data of phosgene and phosgene substitutes.

Phosgene is the only volatile reagent in Table 1. Non-volatile reagents are difficult to remove by simple evaporation. A comparison of the reactivities of phosgene and its substitutes has been investigated and reported (Table 2).

Table 2.Relative reactivities in pseudo first order reactions with methanol.

Many Additional Reactions and Other Useful Information are Available in Phosgenations - A Handbook by Cotarca and Eckert. The Handbook Provides Numerous Safe Phosgenation Procedures. 

Phosgene is 170 times more reactive than TP, the main phosgene substitute. Therefore, reactions with phosgene can be carried out under much milder conditions than with TP. Compounds will react faster and at lower temperatures (often at -78 ยฐC), preserving sensitive moieties against attack- a weighty argument when considering high-priced compounds.

When using phosgene substitutes, the removal of excess reagent is often problematic during the workup of a reaction. Since the substitutes are non-volatile, purification requires an extra distillation or recrystallization step. Only phosgene can easily and quantitatively be separated from the product by evaporation or stripping with nitrogen, as it is the lone volatile reagent of the group. Therefore, products resulting from reactions with phosgene are mostly of high purity and can be directly reacted further without investing additional time in cost-intensive purification.

Another method used to remove phosgene substitutes from the desired products is to destroy them with appropriate nucleophiles such as water or alcohols. This method can be applied only when the product is not sensitive to those nucleophiles, as is the case for carbamates, carbonates, ureas, cyanides, isocyanides, and alkyl chlorides. But chloroformates, carbamoyl chlorides, isocyanates, acyl chlorides, N-carboxylic anhydrides, and carbodiimides cannot be purified by this method. These groups are advantageously synthesized by use of phosgene to give these functional groups quickly and easily.

For example, regarding the synthesis of methyl 2-isocyanato-3-phenyl-2-butenoate by dehydration of the corresponding saturated compound with either phosgene or diphosgene, product yields are 68% and 54% respectively. The products are of quite different purities as demonstrated by their boiling points: the product prepared with DP has a boiling range of 90-110 ยฐC/0.001 mmHg, whereas the product prepared with phosgene has a sharp boiling point of 90 ยฐC/0.07 mmHg. Effenberger writes: "In the reaction phosgene is distinctly superior to diphosgene."

In optimizations by Eckert of the production of benzyl chloroformate (Z-Cl) from benzyl alcohol using triphosgene, they demonstrate that product yields do not exceed 15%. However, when phosgene is used as the chloroformylation reagent, the reaction affords 97% Z-Cl after distillation of the crude product.

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