Configuration interaction calculations of annihilation rates for positronic complexes of alkali hydrides

Buenker, Robert J.; Liebermann, Heinz‐Peter

doi:10.1016/j.nimb.2009.01.012

Nuclear Instruments and Methods in Physics Research Section B:

2009

DOI: 10.1016/j.nimb.2009.01.012

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Configuration interaction calculations of annihilation rates for positronic complexes of alkali hydrides

Robert J. Buenker

Heinz‐Peter Liebermann

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Cited by 5 publications

(2 citation statements)

References 21 publications

(35 reference statements)

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“…Theoretical calculations of positron binding energies and annihilation rates have been performed using many of the standard tools of computational chemistry. Positron binding to atoms and molecules has been studied using wavefunction expansions in explicitly correlated Gausians with the stochastic variational method (ECG-SVM) [16][17][18][19][20][21][22][23][24] , configuration interaction (CI) methods [25][26][27][28][29][30][31] , and quantum Monte Carlo (QMC) methods [32][33][34][35][36][37][38][39][40] . The annihilation rate and lifetime of positrons in solids, particularly in the presence of defects, has been studied using density functional theory 41,42 and quantum Monte Carlo methods 43,44 .…”

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confidence: 99%

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Neural network variational Monte Carlo for positronic chemistry

Cassella,

Foulkes,

Pfau

et al. 2024

Nat Commun

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Quantum chemical calculations of the ground-state properties of positron-molecule complexes are challenging. The main difficulty lies in employing an appropriate basis set for representing the coalescence between electrons and a positron. Here, we tackle this problem with the recently developed Fermionic neural network (FermiNet) wavefunction, which does not depend on a basis set. We find that FermiNet produces highly accurate, in some cases state-of-the-art, ground-state energies across a range of atoms and small molecules with a wide variety of qualitatively distinct positron binding characteristics. We calculate the binding energy of the challenging non-polar benzene molecule, finding good agreement with the experimental value, and obtain annihilation rates which compare favourably with those obtained with explicitly correlated Gaussian wavefunctions. Our results demonstrate a generic advantage of neural network wavefunction-based methods and broaden their applicability to systems beyond the standard molecular Hamiltonian.

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confidence: 99%

“…This results in very slow convergence of CI calculations with the maximum angular momentum of functions included in the basis. Furthermore, the positronic density is typically highly diffuse, requiring the augmentation of standard basis sets with additional diffuse basis functions 27,[29][30][31] .…”

mentioning

confidence: 99%

Neural network variational Monte Carlo for positronic chemistry

Cassella,

Foulkes,

Pfau

et al. 2024

Nat Commun

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Ab initio study of the positronation of the CaO and SrO molecules including calculation of annihilation rates

Buenker

Liebermann

2012

J Comput Chem

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Ab initio multireference single- and double-excitation configuration interaction calculations have been performed to compute potential curves for ground and excited states of the CaO and SrO molecules and their positronic complexes, e(+)CaO, and e(+)SrO. The adiabatic dissociation limit for the (2)Σ(+) lowest states of the latter systems consists of the positive metal ion ground state (M(+)) and the OPs complex (e(+)O(-)), although the lowest energy limit is thought to be e(+)M + O. Good agreement is found between the calculated and experimental spectroscopic constants for the neutral diatomics wherever available. The positron affinity of the closed-shell X (1)Σ(+) ground states of both systems is found to lie in the 0.16-0.19 eV range, less than half the corresponding values for the lighter members of the alkaline earth monoxide series, BeO and MgO. Annihilation rates (ARs) have been calculated for all four positronated systems for the first time. The variation with bond distance is generally similar to what has been found earlier for the alkali monoxide series of positronic complexes, falling off gradually from the OPs AR value at their respective dissociation limits. The e(+)SrO system shows some exceptional behavior, however, with its AR value reaching a minimum at a relatively large bond distance and then rising to more than twice the OPs value close to its equilibrium distance.

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Toward a regional quantum description of the positronic systems: Primary considerations

Nasertayoob

Goli

Shahbazian

2011

Int J of Quantum Chemistry

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This article presents the foundations of a regional quantum description of the positronic systems; molecules containing positron(s), the antielectron. It is demonstrated that by introducing a novel scalar function, called l-field, it is possible to construct a positronic local zero-flux equation. This equation is the basis of the topological analysis of the quantum structure as well as delineating the boundaries of the positronic subsystems, which are 3D regions with well-defined regional kinetic energies. Furthermore, the positronic subsystem hypervirial theorem is proposed, which yields the regional quantum theorems for the positronic subsystems. The regional virial, force, and continuity theorems are all derivable from the positronic subsystem hypervirial theorem. The primary computational considerations on LiH,e þ illustrate that the positronic zero-flux equation results to reasonable subsystems; that is, to 3D regions similar to those derived previously in purely electronic systems. The general approach proposed in this study is extendable to other exotic species and pave the way toward a unified regional description of these systems.

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Configuration interaction calculations of annihilation rates for positronic complexes of alkali hydrides

Cited by 5 publications

References 21 publications

Neural network variational Monte Carlo for positronic chemistry

Neural network variational Monte Carlo for positronic chemistry

Ab initio study of the positronation of the CaO and SrO molecules including calculation of annihilation rates

Toward a regional quantum description of the positronic systems: Primary considerations

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