Respuesta :
Answer: Cn-
Explanation:
According to Lewis theory, the most stable species will have a complete octet state for as many atoms as possible. From constructing Lewis dot structures for each specie You should be able to see that CN+ cannot give a complete octet to the C atom unless a quadruple bond - unknown except in transition metals - is formed. CN will have an odd number of electrons, and is thus a free radical and also unstable with respect to dimerization (forms cyanogen). CN-, gives both C and N a complete octet with a triple bond, and is therefore the most stable among the three.
Molecular orbital theory is a bit more complex. Nitrogen and carbon are close in electronegativity, therefore the orbitals from the C atom will combine with the same orbitals from the N atom. The molecular orbitals produced will be sigma2s, sigma*2s, pi2p, sigma2p, pi*2p, and sigma*2p. The * denotes an anti bonding orbital, they are higher in energy, and electrons placed into these orbitals weaken the bonding between two atoms. CN+ will completely fill the sigma2s, sigma*2s, and pi2p orbitals. CN will add an electron in the bonding sigma2p orbital, and the atoms are therefore more strongly bonded than in CN+. CN- fills the sigma2p orbital, and the addition of another bonding electron means that this species has the strongest bond of the three. I might have the names of some of the filled levels incorrect; the energy levels of the sigma2p and pi2p swap at some point. This concept is hard to explain without a picture; see the link.
Therefore, both MO and Lewis theories predict CN- as the more stable specie, a prediction that is in line with experimental data.
