Cyanoform

Abstract: Although listed in organic chemistry textbooks as one of the strongest carbon acids, and in spite of more than a hundred years of attempts to prepare the compound, tricyanomethane (cyanoform) has resisted isolation and characterization, either as the carbon-acid 1 or as the dicyanoketenimine tautomer 2. Only in the vapor phase at very low pressure has the compound been identified from its microwave spectrum. Here we review and partially repeat the preparative work. With the aid of spectroscopic and diffraction methods (including powder diffraction) we have identified some of the products obtained as: hydronium tricyanomethanide (3), (Z)-3-amino-2-cyano-3-iminoacrylimide (4), a co-crystal of 4 with sulfuric acid (or corresponding iminium salt), and an addition product of 2 with hydrochloric acid (5/6). Quantum-mechanical calculations at the MP2/6-311 + +g(2d,2p) level have been made to assess the relative energies of some of the molecules involved.

Abstract: Although the chemistry of elusive tricyanomethane (cyanoform) has been studied during a period of more than 150 years, this compound has very rarely been utilized in the synthesis or modification of heterocycles. Three-membered heterocycles, such as epoxides, thiirane, aziridines, or 2H-azirines, are now treated with tricyanomethane, which is generated in situ by heating azidomethylidene-malonodinitrile in tetrahydrofuran at 45 °C or by adding sulfuric acid to potassium tricyanomethanide. This leads to ring expansion with formation of 2-(dicyanomethylidene)oxazolidine derivatives or creation of the corresponding thiazolidine, imidazolidine, or imidazoline compounds and opens up a new access to these push-pull-substituted olefinic products. The regio- and stereochemistry of the ring-enlargement processes are discussed, and the proposed reaction mechanisms were confirmed by using 15 N-labeled substrates. It turns out that different mechanisms are operating; however, tricyanomethanide is always acting as a nitrogen-centered nucleophile, which is quite unusual if compared to other reactions of this species.