Theoretical calculation of the vib-rotational interaction potential and the partial wave cross sections for He-H2(D2, T2) system

The interaction potential surfaces of He-HD (HT, DT) are calculated by employing ab initio method at the CCSD(T)/AUG-CC-PV5Z +bf(3s3p2d1f) calculational level when the key-lengths of target-molecule are different. The vib-rotational interaction potentials of He-HD (HT, DT) system are fitted using the method of center of mass transformation-fitting, the Tang-Toennies potential function and nonlinear least square method at the incident angles of 0°, 20°, 40°, 60°, 80°, 90°, 100°, 120°, 140°, 160° and 180°. The differential coefficient cross sections at the energies of 60, 90 and 120 meV are calculated by using the quantum close-coupling method. On the basis of the above result, the change rules of the differential coefficient cross section with incident energy, reduced mass of system and scattering angle are discussed.

Theoretical calculation of the vib-rotational interaction potential and the differential coefficient cross sections for He-HD (HT, DT) system

沈光先¹,

汪荣凯²,

令狐荣锋³

et al. 2012

Study on ro-vibrational excitation cross sections of Ne-HF

Mei¹,

Wang²,

Rong-Feng³

et al. 2013

In this paper, the QCISD(T) method and aug-cc-pVTZ basic set are used to calculate the interactional potential of Ne atom and halogen hydride molecule HF, in which Boys and Bernardi's full counterpoise method is employed to eliminate the basis set superposition error. After obtaining the interactional potential energy data in eleven directions for He-HF, the symmetric potential V0 and the anisotropic potentials V1, V2, V3, etc. of the system are derived, by using Huxley function fitting, so as to describe well the He-HF potential energy surface. Finally, the close-coupling method is used to calculate the total collision excitation cross section, elastic partial wave cross section and inelastic elastic partial wave cross section.

Theoretical calculation of the vib-rotational interaction potential and the scattering cross section for the Ar-H2 (D2, T2) collision system

底马可¹,

沈光先²,

赵云强³

et al. 2015

Based on the ab initio coupled-cluster CCSD(T) method in quantum mechanics, the charge distribution of Ar atom and its vib-rotational interaction with H2 molecule are calculated using augmented correlation consistent basis sets aug-cc-pV5Z and 3s3p2d1f1g Gaussian bonding function, and the basis set superposition error (BSSE) is eliminated using Boy and Bernardi's full counterpoise method. Afterwards, the analytical expression of the interaction potential of the Ar-H2 system is fitted with Tang-Toennies potential function. With this interaction potential, the scattering cross section of Ar-H2(D2, T2) collision system is calculated by using close-coupling method when the incident energy of Ar atoms is 83 meV. The calculated differential cross section of Ar-D2 collision system is consistent with the experimental results. Calculated result and analysis show that the dispersion energy plays a key role in the long-range attractive potential scattering, and the exchange energy plays an important role in the short-range repulsive potential scattering. The direction of the radial dipole of the Ar-H2 (D2, T2) collision system is turned twice in the range of impact parameters from 0.27 to 0.47 nm.