29 research outputs found
Vibrational and rotational quenching of CO by collisions with H, He, and H2
Collisional quenching of molecular species is an important process in a variety of astrophysical environments including interstellar clouds, photodissociation regions, and cool stellar/planetary atmospheres. In this work, quantum mechanical scattering calculations are presented for the rotational and vibrational relaxation of rotationally-excited CO due to collisions with H, He and H2 for collision energies between 10(exp -6) and approx.15000/cm. The calculations were performed using the close-coupling approach and the l-labeled form of the coupled-states approximation. Cross sections and rate coefficients for the quenching of the v=0-2, j=0-6 levels of CO are presented and comparisons with previous calculations and measurements, where available, are provided
Rotational quenching of CO due to H collisions
Rate coefficients for state-to-state rotational transitions in CO induced by
both para- and ortho-H collisions are presented. The results were obtained
using the close-coupling method and the coupled-states approximation, with the
CO-H interaction potential of Jankowski & Szalewicz (2005). Rate
coefficients are presented for temperatures between 1 and 3000 K, and for
CO() quenching from to all lower levels. Comparisons
with previous calculations using an earlier potential show some discrepancies,
especially at low temperatures and for rotational transitions involving large
. The differences in the well depths of the van der Waals
interactions in the two potential surfaces lead to different resonance
structures in the energy dependence of the cross sections which influence the
low temperature rate coefficients. Applications to far infrared observations of
astrophysical environments are briefly discussed.Comment: 28 pages, 10 figure
Inelastic, Exchange, and Reactive Processes in Rovibrationally Excited Collisions of HD With H
The HD molecule is an important coolant in early universe chemistry models and a tracer of H2 in star-forming regions. Rate coefficients for collisional excitation and de-excitation of HD rotational and vibrational levels form important ingredients in astrophysical models. While collisions with He, H2, and H are the most important, available data for H + HD collisions are largely limited to temperatures less than 1000 K for the vibrational ground state, low-lying rotational levels of the v = 1 HD vibrational level, or computed without reactive contributions. Here, through explicit quantum scattering calculations, we report extensive data for rovibrational transitions in HD induced by H atoms for a range of rotational levels in v = 1 and some v = 0 levels for temperatures up to 1000 K. The significance of the computed results for astrophysical modeling is discussed
QUANTUM CALCULATION OF INELASTIC CO COLLISIONS WITH H. I. ROTATIONAL QUENCHING OF LOW-LYING ROTATIONAL LEVELS
ABSTRACT New quantum scattering calculations for rotational deexcitation transitions of CO induced by H collisions using two CO-H potential energy surfaces (PESs) from Shepler et al. are reported. State-to-state rate coefficients are computed for temperatures ranging from 1 to 3000 K for CO(v = 0, j) deexcitation from j = 1 to 5 to all lower j levels, with j being the rotational quantum number. Different resonance structures in the cross sections are attributed to the differences in the anisotropy and the long-range van der Waals well depths of the two PESs. These differences affect rate coefficients at low temperatures and give an indication of the uncertainty of the results. Significant discrepancies are found between the current rate coefficients and previous results computed using earlier potentials, while the current results satisfy expected propensity rules. Astrophysical applications to modeling far infrared and submillimeter observations are briefly discussed