Ab initio and molecular-dynamics studies on rare gas hydrides: Potential-energy curves, isotropic hyperfine properties, and matrix cage trapping of atomic hydrogen
T. Kiljunen et al., Ab initio and molecular-dynamics studies on rare gas hydrides: Potential-energy curves, isotropic hyperfine properties, and matrix cage trapping of atomic hydrogen, J CHEM PHYS, 110(24), 1999, pp. 11814-11822
Ground-state potential-energy curves and distance dependent isotropic hyper
fine coupling (IHC) constants for ground-state H-RG (=Ne, Ar, Kr, Xe) are o
btained at CCSD(T) (coupled-cluster single double triple) and MP4(SDQ) (fou
rth-order Moller-Plesset single double quadruple) levels, respectively, wit
h an augmented basis set aug-Stuttgart (RG)/aug-cc-pVQZ (H). The obtained R
-m and epsilon are for NeH: 3.45 Angstrom and -1.36 meV; ArH: 3.65 Angstrom
and -3.48 meV; KrH: 3.75 Angstrom and -4.32 meV; XeH: 3.90 Angstrom and -5
.22 meV. The computed pair potentials are utilized in classical molecular-d
ynamics simulations of H-RG lattices. Along the classical trajectory, the m
any-body perturbation on the H atom hyperfine coupling constant is computed
by pair-wise addition of the individual RG-H contributions obtained from t
he present quantum-chemical calculations. The computed IHC shifts are compa
red with electron paramagnetic resonance (EPR) spectra obtained in low-temp
erature matrix isolation experiments. For most cases this theoretical treat
ment agrees very well with the experiment and confirms the previous site as
signments. However, for H-Xe, the theory would suggest stability of both in
terstitial O-h and substitutional sites, whereas only one site is observed
in the experiment. Based on the present calculations this site can be assig
ned as a nearly undistorted substitutional site. (C) 1999 American Institut
e of Physics. [S0021-9606(99)31124-7].