2024-03-29T15:06:59Zhttp://digital.csic.es/dspace-oai/requestoai:digital.csic.es:10261/282022021-11-12T10:20:24Zcom_10261_14181com_10261_4col_10261_14182
2010-10-05T13:18:38Z
urn:hdl:10261/28202
Communications: a model study on the electronic predissociation of the NeBr2 van der Waals complex
Sanz-Sanz, Cristina
Roncero, Octavio
Hernández-Lamoneda, Ramón
Pio, Jordán M.
Taylor, Molly A.
Janda, Kenneth C.
Ab initio calculations
Energy gap
Potential energy surfaces
Predissociation
Quasimolecules
Radiative lifetimes
4 pags. ; 2 figs.
Recently, the predissociation lifetimes of the NeBr2(B) complex for different initial vibrational excitation (10 ≤ v′ ≤ 20) have been measured using time-resolved optical pump-probe spectroscopy [ Taylor et al., J. Chem. Phys., 132, 104309 (2010) ]. In the vibrational interval studied, the vibrational predissociation (VP) proceeds by the transfer of a single vibrational quantum and the lifetimes are expected to decrease smoothly with increasing v′, as predicted by the energy gap law. However, the experimental lifetimes show strong oscillations with v′, which were attributed to the occurrence of electronic predissociation into two possible dissociative electronic states of Br2(1g,2g), based on a Franck–Condon spectator model. In this work we reproduce the experimental findings by performing full three-dimensional wave packet calculations for the competition of vibrational and electronic predissociation, including the B(0u+), 2g, and C(1u) electronic states. Model potential energy surfaces were used based on previous theoretical simulations of the VP dynamics on the B state and on ab initio calculations on the NeCl2 related system. Thus, only two parameters, the strength of the electronic couplings, are fit to achieve the excellent theoretical/experimental agreement.
2010-10-05T13:18:38Z
2010-10-05T13:18:38Z
2010-06-10
artículo
The journal of chemical physics, 132 (22): 221103 (2010)
0021-9606)
http://hdl.handle.net/10261/28202
10.1063/1.3429940
eng
http://dx.doi.org/10.1063/1.3429940
openAccess
American Institute of Physics