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PO+−He collision: <i>ab initio</i> potential energy surface and inelastic rotational rate coefficients

Pooja Chahal, T. J. Dhilip Kumar

2023Monthly Notices of the Royal Astronomical Society12 citationsDOIOpen Access PDF

Abstract

ABSTRACT Computations involving quantum dynamics are performed to attain cross-sections corresponding to rotational de-excitation and excitation rates of the PO+ species including four rotational lines recently detected in the interstellar molecular clouds. New ab initio potential energy surface (PES) for PO+−He collision is constructed by using CCSD(T) method and basis set extrapolated to complete basis set limit (CBS) considering a rigid rotor approximation. The PES is then trained to create neural network (NN) model to construct an augmented surface with angular coordinates at 1° intervals. The PES has a global minimum located at $\theta =110{}^{\circ }$ and R = 3.1 Å. An analytical fitting is performed on the NN surface to obtain the first 41 radial coefficients needed to solve the equations of the coupled-channel method. The essentially precise close coupling approach is used to compute the rotational (de-)excitation cross-sections till 1400 cm−1 with rotational states converged up to 26. Further, these cross-sections are thermally averaged to get the rate coefficients for various rotational transitions till 200 K. The propensity rule favours the odd transitions (Δj = 1) for the current study. The rate for the transition 5 → 4 is found to be higher than transition 1→ 0 by a factor of 3.1 at T = 20 K that decreases to 2.1 at T = 100 K.

Topics & Concepts

PhysicsAb initioExcitationAtomic physicsPotential energy surfaceCollisional excitationInelastic collisionRigid rotorBasis setRotational transitionRotational energySurface (topology)CollisionQuantum mechanicsRotor (electric)Angular momentumGeometryMoleculeMathematicsIonizationComputer scienceElectronIonComputer securityAdvanced Chemical Physics StudiesSpectroscopy and Laser ApplicationsMolecular Spectroscopy and Structure