The anomalous behavior of the Zeeman anticrossing spectra of {tilde {ital A}}{sup 1}A{sub {ital u}} acetylene: Theoretical considerations
- The Center for Computational Quantum Chemistry, The University of Georgia, Athens, Georgia 30602 (United States)
P. Dupr{acute e}, R. Jost, M. Lombardi, P. G. Green, E. Abramson, and R. W. Field have observed anomalous behavior of the anticrossing density in the Zeeman anticrossing (ZAC) spectra of gas phase {tilde {ital A}}{sup 1}A{sub {ital u}} acetylene in the 42200 to 45300 cm{sup {minus}1} energy range. To best explain this result, they hypothesize a large singlet{endash}triplet coupling due to the existence of a linear isomerization barrier connecting a triplet-excited {ital cis}- and {ital trans}-acetylene in the vicinity of the studied energy range ({approximately}45500 cm{sup {minus}1}). Theoretically such a linear stationary point, however, must have two different degenerate bending vibrational frequencies which are either imaginary or exactly zero. Neither case has yet been experimentally detected. Here, we have studied the two lowest-lying linear triplet-excited-state stationary points of acetylene, {sup 3}{Sigma}{sup +}{sub {ital u}} and {sup 3}{Delta}{sub {ital u}}, to see if they fit Dupr{acute e} {ital et} {ital al}.{close_quote}s hypothesis. We have completed geometry optimization and harmonic vibrational frequency analysis using complete-active-space self-consistent field (CASSCF) wave functions as well as determined energy points at those geometries using the second-order configuration interaction (SOCI) method. Harmonic vibrational analyses of both stationary points reveal two different doubly degenerate vibrational modes with imaginary vibrational frequencies (or negative force constants) indicating that they are indeed saddle points with a Hessian index of four. At the DZP SOCI//CASSCF level of theory with zero-point vibrational energy (ZPVE) correction, the {sup 3}{Sigma}{sup +}{sub {ital u}} stationary point lies 35840 cm{sup {minus}1} above the ground state of acetylene. This is much too low in energy to contribute to the ZAC spectral anomaly. (Abstract Truncated)
- DOE Contract Number:
- FG05-94ER14428
- OSTI ID:
- 278433
- Journal Information:
- Journal of Chemical Physics, Vol. 104, Issue 5; Other Information: PBD: Feb 1996
- Country of Publication:
- United States
- Language:
- English
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