Coupled states cross sections for rotational excitation of H2CO by He impact at interstellar temperatures
- 15 January 1977
- journal article
- research article
- Published by AIP Publishing in The Journal of Chemical Physics
- Vol. 66 (2) , 531-536
- https://doi.org/10.1063/1.433972
Abstract
Cross sections for rotational excitation of ortho formaldehyde due to collision with helium are computed following the coupled states (CS) formalism and compared with recent coupled channel (CC) results obtained employing the same ab initio configuration interaction intermolecular potential. The CS equations are integrated at 9 scattering energies between 25 and 95°K using a basis set of 16 ortho H2CO states (1⩽j⩽5). The CS procedure with the orbital angular momentum quantum number l set equal to the total angular momentum J yields the correct order of magnitude for scattering cross sections. Qualitative differences are found, however, in the energy dependence of some inelastic transitions.Keywords
This publication has 25 references indexed in Scilit:
- Coupled-channel study of rotational excitation of a rigid asymmetric top by atom impact: (H2CO,He) at interstellar temperaturesThe Journal of Chemical Physics, 1976
- Sufficiency conditions for the validity of the j z-conserving coupled states approximationThe Journal of Chemical Physics, 1976
- The dimensionality and choice of effective Hamiltonians for molecular collisionsThe Journal of Chemical Physics, 1975
- Approximations for the rotational excitation of molecules by atomsThe Journal of Chemical Physics, 1975
- Coupled-states approach for elastic and for rotationally and vibrationally inelastic atom–molecule collisionsThe Journal of Chemical Physics, 1975
- Quantum mechanical close coupling approach to molecular collisions. jz -conserving coupled states approximationThe Journal of Chemical Physics, 1974
- Space-fixed vs body-fixed axes in atom-diatomic molecule scattering. Sudden approximationsThe Journal of Chemical Physics, 1974
- A Survey of Interstellar Formaldehyde in Dust CloudsThe Astrophysical Journal, 1973
- Microwave Absorption of the 2_12 -> 2_11 Rotational Transition in Interstellar FormaldehydeThe Astrophysical Journal, 1970
- A Pumping Mechanism for Anomalous Microwave Absorption in Formaldehyde in Interstellar SpaceThe Astrophysical Journal, 1969