Many-body theory calculations of positronic-bonded molecular dianions

Abstract

The energetic stability of positron di-anion systems [A-;e+;A-] is studied via many-body theory, where A- includes H-, F-, Cl- and the molecular anions (CN)- and (NCO)-. Specifically, the energy of the system as a function of ionic separation is determined by solving the Dyson equation for the positron in the field of the two anions, using a positron-anion self energy as constructed in [J. Hofierka, B. Cunningham, C. M. Rawlins, C. H. Patterson and D. G. Green, Nature 606 688 (2022)] that accounts for correlations including polarization, screening, and virtual-positronium formation. Calculations are performed for a positron interacting with H22-, F22-, and Cl22-, and are found to be in good agreement with previous theory. In particular, we confirm the presence of two minima in the potential energy of the [H-;e+;H-] system with respect to ionic separation: one a positronically-bonded [H-;e+;H-] local minimum at ionic separations r3.4~, and a global minimum at smaller ionic separations r1.6~ that gives overall instability of the system with respect to dissociation into a H2 molecule and a positronium negative ion, Ps-. The first predictions are made for positronic bonding in dianions consisting of molecular anionic fragments, specifically for (CN)22-, and (NCO)22-. In all cases we find that the molecules formed by the creation of a positronic bond are stable relative to dissociation into A- and e+A- (positron bound to a single anion), with bond energies on the order of 1~eV and bond lengths on the order of several angstroms.

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