Theoretical potential energy function and rovibronic spectrum of CO+2(X 2Πg)

Abstract

For the electronic ground state of CO⁺₂ the three‐dimensional potential energy, electric dipole, and transition moment functions have been calculated from highly correlated multireference configuration interaction electronic wave functions. Along the antisymmetric stretching displacements the shape of the potential energy functions is found to be very sensitive to the electron correlation effect. Using a modified theoretical potential energy function rovibronic energy levels have been calculated variationally by the method of Carter and Handy. In this approach, anharmonicity, rotation–vibration, electronic angular momenta, and electron spin coupling effects have been accounted for. The vibronic band origins agree to within about 10 to 20 cm⁻¹ with the available experimental data, and the rotational levels agree to within 0.01 cm⁻¹ for low J values. Additional vibrational band origins have been predicted for energies up to 3200 cm⁻¹. The anomalously low frequency of the antisymmetric stretching mode and its inverse anharmonicity in the X ²Π_g state of CO⁺₂ have been reproduced with the potential energy functions for the adiabatic states. Previously, it has been assumed that this effect is due to the vibronic coupling. The molecular parameters of one‐dimensional effective Hamiltonians obtained from fits of the spectral data are compared with those derived from the theoretical potential.