A. R. Swann scite author profile

Positronium (Ps) scattering by noble-gas atoms (He, Ne, Ar, Kr, and Xe) is studied in the frozen-target approximation and with inclusion of the van der Waals interaction. Single-particle electron and positron states in the field of the target atom are calculated, with the system enclosed by a hard spherical wall. The two-particle Ps wave function is expanded in these states, and the Hamiltonian matrix is diagonalized, giving the Ps energy levels in the cavity. Scattering phase shifts, scattering lengths, and cross sections are extracted from these energies and compared with existing calculations and experimental data. Analysis of the effect of the van der Waals interaction shows that it cannot explain the recent experimental data of Brawley et al. for Ar and Xe [Phys. Rev. Lett. 115, 223201 (2015)].

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Positron Binding and Annihilation in Alkane Molecules

Swann

Gribakin

2019

Phys. Rev. Lett.

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A model-potential approach has been developed to study positron interactions with molecules. Binding energies and annihilation rates are calculated for positron bound states with a range of alkane molecules, including rings and isomers. The calculated binding energies are in good agreement with experimental data, and the existence of a second bound state for n-alkanes (C n H 2n+2 ) with n ≥ 12 is predicted in accord with experiment. The annihilation rate for the ground positron bound state scales linearly with the square root of the binding energy.

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Calculations of positron binding and annihilation in polyatomic molecules

Swann

Gribakin

2018

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A model-potential approach to calculating positron-molecule binding energies and annihilation rates is developed. Unlike existing ab initio calculations, which have mostly been applied to strongly polar molecules, the present methodology can be applied to both strongly polar and weakly polar or nonpolar systems. The electrostatic potential of the molecule is calculated at the Hartree-Fock level, and a model potential that describes short-range correlations and long-range polarization of the electron cloud by the positron is then added. The Schrödinger equation for a positron moving in this effective potential is solved to obtain the binding energy. The model potential contains a single adjustable parameter for each type of atom present in the molecule. The wave function of the positron bound state may be used to compute the rate of electron-positron annihilation from the bound state. As a first application, we investigate positron binding and annihilation for the hydrogen cyanide (HCN) molecule. Results for the binding energy are found to be in accord with existing calculations, and we predict the rate of annihilation from the bound state to be Γ = 0.1-0.2 × 10 9 s −1 .

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Positronium collisions with rare-gas atoms

Gribakin¹,

Swann²,

Wilde³

et al. 2016

J. Phys. B: At. Mol. Opt. Phys.

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Abstract. We calculate elastic scattering of positronium (Ps) by the Xe atom using the recently developed pseudopotential method Phys. Rev. A 90 052717] and review general features of Ps scattering from heavier rare-gas atoms: Ar, Kr and Xe. The total scattering cross section is dominated by two contributions: elastic scattering and Ps ionization (break-up). To calculate the Ps ionization cross sections we use the binary-encounter method for Ps collisions with an atomic target. Our results for the ionization cross section agree well with previous calculations carried out in the impulse approximation. Our total Ps-Xe cross section, when plotted as a function of the projectile velocity, exhibits similarity with the electron-Xe cross section for the collision velocities higher than 0.8 a.u., and agrees very well with the measurements at Ps velocities above 0.5 a.u.

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Effective radius of ground- and excited-state positronium in collisions with hard walls

et al. 2017

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We determine effective collisional radii of positronium (Ps) by considering Ps states in hard-wall spherical cavities. B-spline basis sets of electron and positron states inside the cavity are used to construct the states of Ps. Accurate Ps energy eigenvalues are obtained by extrapolation with respect to the numbers of partial waves and radial states included in the bases. Comparison of the extrapolated energies with those of a pointlike particle provides values of the effective radius ρ nl of Ps(nl) in collisions with a hard wall. We show that for 1s, 2s, and 2p states of Ps, the effective radius decreases with the increasing Ps center-of-mass momentum, and find ρ 1s = 1.65 a.u., ρ 2s = 7.00 a.u., and ρ 2p = 5.35 a.u. in the zero-momentum limit.

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A. R. Swann

Calculations of positronium-atom scattering using a spherical cavity

Positron Binding and Annihilation in Alkane Molecules

Calculations of positron binding and annihilation in polyatomic molecules

Positronium collisions with rare-gas atoms

Effective radius of ground- and excited-state positronium in collisions with hard walls

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