Collision induced transitions between the A 2Πi(v=0) and X 2Σ+(v=10) states of CO+

Abstract

We report on a laser double resonance study of collisional electronic transfer between the A ²∏_i(v=0) and X ²Σ⁺(v=10) states of CO⁺. In particular, we have selectively populated individual rotational levels of the A ²∏_i(v=0) manifold of CO⁺ with a pump laser and probed the adjacent X ²Σ⁺(v=10) manifold with a second pulsed laser. The only other molecules studied by this technique, N⁺₂ and CN, are isoelectronic to CO⁺ and have efficient collisional transfer between their analogous A and X states even though perturbations are nonexistent or negligible. The pair of vibronic levels selected for CO⁺ has a zero energy gap and a much smaller Franck–Condon factor (FCF) than those studied for the A and X states of N⁺₂ and CN. Previous works have indicated that the FCF is not important in these electronic transfer processes. We find, however, that unlike N⁺₂ and CN, rapid collisional transfer between unperturbed rotational levels of the A ²∏_i(v=0) and X ²∑⁺(v=10) electronic states of CO⁺ is not observed. Efficient electronic transfer occurred only through the perturbed levels of these two manifolds. In addition, we find that of the two spin components that make up the A ²∏_i(v=0) rotational manifold, the propensity for collisional e↔f rotational transfer is more favorable for the ²∏_3/2 member in agreement with theoretical considerations.