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Rotational quenching of an interstellar gas thermometer: CH<sub>3</sub>CN⋯He collisions

M. Ben Khalifa, Ernesto Quintas‐Sánchez, Richard Dawes, K. Hammami, L. Wiesenfeld

2020Physical Chemistry Chemical Physics18 citationsDOI

Abstract

Among all the molecular species found in the interstellar medium, molecules with threefold symmetry axes play a special role, as their rotational spectroscopy allows them to act as practical gas thermometers. Methyl-cyanide (CH3CN) is the second most abundant of those (after ammonia). We compute in this paper the collisional dynamics of methyl-cyanide in collision with helium, for both the A- and the E-symmetries of CH3CN. The potential energy surface is determined using the CCSD(T)-F12b formalism and fit with convenient analytic functions. We compute the rotationally inelastic cross sections for all levels up to 510 cm-1 of collision energy, employing at low energy exact Coupled Channels methods, and at higher energies, approximate Coupled States methods. For temperatures from 7 K up to 300 K, rates of quenching are computed and most are found to differ from those reported earlier (up to a factor of a thousand), calling for a possible reexamination of the temperatures assigned to low density gasses.

Topics & Concepts

ThermometerQuenching (fluorescence)Rotational temperaturePhysicsAtomic physicsAstrochemistryChemistryInterstellar mediumPhotochemistryPhysical chemistryMaterials scienceAstrophysicsThermodynamicsFluorescenceMoleculeQuantum mechanicsGalaxyMolecular Spectroscopy and StructureAdvanced Chemical Physics StudiesAtmospheric Ozone and Climate
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