Rovibrational interactions in linear triatomic molecules: a theoretical study in curvilinear vibrational coordinates
A variational solution to the rovibrational problem in curvilinear vibrational coordinates has been implemented and used to investigate the nuclear motions in several linear triatomic molecules, like HCN, OCS, and HCP. The dependence of the rovibrational energy levels on the rotational quantum numbe...
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Zusammenfassung: | A variational solution to the rovibrational problem in curvilinear
vibrational coordinates has been implemented and used to investigate the
nuclear motions in several linear triatomic molecules, like HCN, OCS, and HCP.
The dependence of the rovibrational energy levels on the rotational quantum
numbers and the l-doubling has been studied. Two approximations to the
rovibrational Hamiltonian have been examined, depending on the level of
truncation of the potential energy operator. It turns out that truncation after
the fifth order in the potential is sufficient to produce vibrational energies
of high accuracy. An interesting feature of the present formulation of the
problem in terms of the curvilinear vibrational coordinates is the explanation
for the l-doubling of the rovibrational levels, which in this picture is
interpreted as the result of the inequivalency of the average rotational
constants in mutually perpendicular planes, rather than as the effect of the
Coriolis-type interactions between the vibrational and rotational motions. The
present theoretical results are compared with the available experimental data
from high-resolution spectroscopy, as well as with other ab initio
calculations. |
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DOI: | 10.48550/arxiv.1108.3532 |