6533b82dfe1ef96bd1291e2d

RESEARCH PRODUCT

Quantum-chemical calculation of Born–Oppenheimer breakdown parameters to rotational constants

Cristina PuzzariniJürgen Gauss

subject

Field (physics)ChemistryBiophysicsBorn–Oppenheimer approximationRotational transitionRotational temperatureCondensed Matter PhysicsDiatomic moleculesymbols.namesakesymbolsRotational spectroscopyPhysics::Chemical PhysicsPhysical and Theoretical ChemistryAtomic physicsRotational partition functionAdiabatic processMolecular Biology

description

The paper describes how Born–Oppenheimer breakdown parameters for the rotational constants of diatomic molecules can be determined via quantum-chemical computations. The deviations from the Born–Oppenheimer equilibrium values are accounted for by considering the adiabatic correction to the equilibrium bond distances, the electronic contribution to the rotational constant via the rotational g tensor, and the so-called Dunham correction, which can be computed directly from a polynomial expansion of the potential curve around the equilibrium distance. Calculations for HCl, SiS, and HF demonstrate the accuracy that can be achieved in the theoretical treatment of the considered Born–Oppenheimer breakdown parameters and the usefulness of such calculations is illustrated for highly accurate spectroscopic measurements in the field of rotational spectroscopy.

yearjournalcountryeditionlanguage
2010-02-10Molecular Physics
https://doi.org/10.1080/00268970903433507