Electronic structure, stability, and nature of bonding of the complexes ofC2H2 and C2H4 with H+, Li+, and Na+ ions. Extensive ab initio and density functional study
T. Kar et al., Electronic structure, stability, and nature of bonding of the complexes ofC2H2 and C2H4 with H+, Li+, and Na+ ions. Extensive ab initio and density functional study, J PHYS CH A, 105(32), 2001, pp. 7737-7744
The ground-state geometries of the complexes Of C2H2 and C2H4 with H+, Li+,
and Na+ ions have been optimized at the B3LYP and MP2(full) levels of theo
ry using several basis sets'. The difference in the direction of tilting of
the terminal H atoms noticed in C2H3+ and C2H5+ seems to be an artifact of
the methods of calculation and basis sets. The dissociation energies (DEs)
of the complexes have been calculated using B3LYP, MP2(full) and CCSD(T)=f
ull methods. When ZPE (zero-point energy) and BSSE (basis set superposition
error) corrections are included the DEs at the CCSD(T)=full level of theor
y are obtained for a number of basis sets in very good agreement with the e
xperimental values, wherever available. The nature of bonding of the comple
xes has been deduced on the basis of charge transfer, bond indices, localiz
ed MOs, and topological properties of electron density. Both bond indices a
nd LMOs indicate the presence of three-center bonding in all the complexes.
In the protonated species the bonding is found to be predominantly covalen
t; in the Li+ and Na+ complexes also the covalent interaction plays a fairl
y important role.