The structures of LiNC, NaNC, and KNC: Potential energy surface for the orbiting motion of the metal cation around the CN group

Sets of XNC (X = Li, Na, and K) structures have been investigated using a variety of theoretical methods and basis sets. Two linear and a bridged structure correspond to an energy minimum for LiCN. For NaCN and KCN, the linear isocyanide is a minimum at most levels of theory but becomes a second-order stationary point when correlated levels and large basis sets are used. Two transition structures are involved in the interconversion of the bridged form and each linear isomer. The isomerization of the bridged minimum to the linear XCN involves a substantial barrier in each case, so that the satellite motion of the metal is facile at one end but not at the other. Calculations with large basis sets and with electron correlation, fourth-order Merller-Plesset theory for KNC, and quadratic configuration interaction [QCISD(T)] for LiNC and NaNC give qualitative and quantitative agreement with this experiment. The sodium and potassium cyanide prefer bridged forms, in contrast to the linear isocyanide LiNC. 0 1994 by John Wiley & Sons, Inc. quite low. The triatomic molecule, LiNC, having a lithium cation bound to a CN anion, is a particularly good example of this type of fluxional species. The lithium rotates satellitelike'O around the any Of can be CN fragment. This motion is believed to require