The electric dipole moment of ArH+. Disagreement between theory and experiment

1 June 1989

journal article
research article
Published by AIP Publishing in The Journal of Chemical Physics

Vol. 90 (11) , 6486-6490
https://doi.org/10.1063/1.456314

Abstract

The experimentally determined dipole moment of the ArH⁺ molecular ion (1.4 D, 1.59 D) is in considerable disagreement with previous ab initio calculations (2.2 D). In this work we present further theoretical evidence strongly supporting a dipole moment of 2.1±0.1 D. We have carried out an extensive basis set study and calculated the dipole moment using the coupled cluster analytical energy gradient and polarization propagator techniques. Based on a theoretical determination of the equilibrium rotational g factors for ArH⁺ and ArD⁺ we conclude that the extrapolation of the experimentally determined g factors to their equilibrium values is the main source of the discrepancy between theory and experiment.

Keywords

This publication has 19 references indexed in Scilit:

A solution of the gauge origin problem for the magnetic susceptibility
The Journal of Chemical Physics, 1989
Nuclear spin-spin coupling constant of hydrogen molecule with deuterium (HD)
The Journal of Physical Chemistry, 1988
Determination of the dipole moments of molecular ions from the rotational Zeeman effect by tunable far-infrared laser spectroscopy
Philosophical Transactions of the Royal Society of London. Series A, Mathematical and Physical Sciences, 1988
Determination of the dipole moment of ${ArH}^{+}$ from the rotational Zeeman effect by tunable far infrared laser spectroscopy
Physical Review Letters, 1987
Propagator Methods
Advances in Chemical Physics, 1987
Fully numerical hartree-fock methods for molecules
Computer Physics Reports, 1986
A full coupled-cluster singles and doubles model: The inclusion of disconnected triples
The Journal of Chemical Physics, 1982
Symmetry-adapted coupled-pair approach to the many-electron correlation problem. III. Approximate coupled-pair approaches for the Be atom
Physical Review A, 1981
Connections between molecular structure and certain magnetic effects in molecules
Discussions of the Faraday Society, 1955
Vibrational and Centrifugal Effects on Nuclear Interactions and Rotational Moments in Molecules
Physical Review B, 1952