The 21Σg+ state of 6Li2: Observation, analysis, and examination of the isotope effect

The 7 Li 2 5 1 + g and 6 1 + g states have been studied both experimentally and theoretically. Vibrational levels v = 1-26 of the 5 1 + g state and v = 2-14 of the 6 1 + g state were observed using pulsed optical-optical double resonance technique. The 5 1 + g state has an unusual potential energy c

We calculate the vibrational encrw levels for all three possible isotopic species of the 2 'x: state of Liz and from them deduce a set of Dunham constants. Since the 2 t$ state has substantial ionic character, itsshapc isusual and so is the spacing of its vibrational levels. WC find for 'Liz, Ylo =

Ab initio ~.kulations are performed 10 obtiin potenti energy curves for the X lx', state of Liz and Na\_. and the >; 2~; and A 'C; Ufcs of their anions The A 'Xi 31; curves are fwund IO mtersect the X 'z~>!z curves at lo\\ ener~res and are expected to phy ;! mtljor role in the e-+ hlz -hl-+ 11 proce

We have observed the rotational levels in the v ϭ 2, 3, 5, 6, 7, and 8 vibrational manifolds of the 2 1 ⌬ g state of 7 Li 2 via the A 1 ⌺ u ϩ intermediate levels by ⌬⌳ ϭ 2 transitions. This violation of the ⌬⌳ ϭ 0, Ϯ1 selection rule is due to the interaction with the G 1 ⌸ g state. Band-by-band depe

Interacting rovibrational levels of the F 1 S / g and E 1 S / g states of 6 Li 2 have been excited via the optical-optical doubleresonance process, (F, The resulting fluorescence in the region 7000-11 000 cm 01 , which has been examined at high resolution with a Fourier transform spectrometer, was