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Atoms
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Interactions of Positrons with Matter and Radiation
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Interactions of Positrons with Matter and Radiation

A special issue of Atoms (ISSN 2218-2004).

Deadline for manuscript submissions: closed (30 June 2020) | Viewed by 32297

Printed Edition Available!
A printed edition of this Special Issue is available here.

Special Issue Editor

Dr. Anand K. Bhatia

E-Mail Website
Guest Editor
Heliophysics Science Division, NASA/Goddard Space Flight Center, Greenbelt, MD 20771, USA
Interests: scattering and annihilation of positrons and electrons; Feshbach resonances; photoionization of atoms; muonic physics; Rydberg states; excitation of ions by electron and proton impact and their applications to astrophysics; photoionization; atomic structure calculations; Lamb shift
Special Issues, Collections and Topics in MDPI journals

Special Issue Information

Dear Colleagues,

Positrons can be used to study metallic defects. Positron annihilation experiments have been carried out to identify the defects in complex oxides. Positrons have also been used to study the Bose–Einstein condensation (BEC). Ps-BEC can be used to measure antigravity using atomic interferometers. This Special Issue hopes to bring awareness of the various aspects of positron interactions to the larger physics communities. We invite authors to submit articles from all areas of physics.

Dr. Anand K. Bhatia
Guest Editor

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Keywords

  • Positron Collisions and Annihilation
  • Positron physics
  • Positron interactions

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Published Papers (11 papers)

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Research

Jump to: Review

5 pages, 432 KiB  
Article
A Note on the Opacity of the Sun’s Atmosphere
by Anand. K. Bhatia and William. D. Pesnell
Atoms 2020, 8(3), 37; https://doi.org/10.3390/atoms8030037 - 21 Jul 2020
Cited by 2 | Viewed by 3359
Abstract
The opacity of the atmosphere of the Sun is due to processes such as Thomson scattering, bound–bound transitions and photodetachment (bound–free) of hydrogen and positronium ions. The well-studied free–free transitions involving photons, electrons, and hydrogen atoms are re-examined, while free–free transitions involving positrons [...] Read more.
The opacity of the atmosphere of the Sun is due to processes such as Thomson scattering, bound–bound transitions and photodetachment (bound–free) of hydrogen and positronium ions. The well-studied free–free transitions involving photons, electrons, and hydrogen atoms are re-examined, while free–free transitions involving positrons are considered for the first time. Cross sections, averaged over a Maxwellian velocity distribution, involving positrons are comparable to those involving electrons. This indicates that positrons do contribute to the opacity of the atmosphere of the Sun. Accurate results are obtained because definitive phase shifts are known for electron–hydrogen and positron–hydrogen scattering. Full article
(This article belongs to the Special Issue Interactions of Positrons with Matter and Radiation)
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10 pages, 1934 KiB  
Article
Nature’s Pick-Up Tool, the Stark Effect Induced Gailitis Resonances and Applications
by Chi-Yu Hu and David Caballero
Atoms 2020, 8(3), 32; https://doi.org/10.3390/atoms8030032 - 2 Jul 2020
Cited by 1 | Viewed by 2220
Abstract
A simple universal physical mechanism hidden for more than half a century is unexpectedly discovered from a calculation of low excitation antihydrogen. For ease of reference, this mechanism is named Gailitis resonance. We demonstrate, in great detail, that Gailitis resonances are capable of [...] Read more.
A simple universal physical mechanism hidden for more than half a century is unexpectedly discovered from a calculation of low excitation antihydrogen. For ease of reference, this mechanism is named Gailitis resonance. We demonstrate, in great detail, that Gailitis resonances are capable of explaining p+7Li low energy nuclear fusion, d-d fusion on a Pd lattice and the initial transient fusion peak in muon catalyzed fusion. Hopefully, these examples will help to identify Gailitis resonances in other systems. Full article
(This article belongs to the Special Issue Interactions of Positrons with Matter and Radiation)
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12 pages, 5838 KiB  
Article
Deep Minima in the Triply Differential Cross Section for Ionization of Atomic Hydrogen by Electron and Positron Impact
by C. M. DeMars, S. J. Ward, J. Colgan, S. Amami and D. H. Madison
Atoms 2020, 8(2), 26; https://doi.org/10.3390/atoms8020026 - 29 May 2020
Cited by 9 | Viewed by 2926
Abstract
We investigate ionization of atomic hydrogen by electron- and positron-impact. We apply the Coulomb–Born (CB1) approximation, various modified CB1 approximations, the three body distorted wave (3DW) approximation, and the time-dependent close-coupling (TDCC) method to electron-impact ionization of hydrogen. For electron-impact ionization of hydrogen [...] Read more.
We investigate ionization of atomic hydrogen by electron- and positron-impact. We apply the Coulomb–Born (CB1) approximation, various modified CB1 approximations, the three body distorted wave (3DW) approximation, and the time-dependent close-coupling (TDCC) method to electron-impact ionization of hydrogen. For electron-impact ionization of hydrogen for an incident energy of approximately 76.45 eV, we obtain a deep minimum in the CB1 triply differential cross section (TDCS). However, the TDCC for 74.45 eV and the 3DW for 74.46 eV gave a dip in the TDCS. For positron-hydrogen ionization (breakup) we apply the CB1 approximation and a modified CB1 approximation. We obtain a deep minimum in the TDCS and a zero in the CB1 transition matrix element for an incident energy of 100 eV with a gun angle of 56.13 ° . Corresponding to a zero in the CB1 transition matrix element, there is a vortex in the velocity field associated with this element. For both electron- and positron-impact ionization of hydrogen the velocity field rotates in the same direction, which is anticlockwise. All calculations are performed for a doubly symmetric geometry; the electron-impact ionization is in-plane and the positron-impact ionization is out-of-plane. Full article
(This article belongs to the Special Issue Interactions of Positrons with Matter and Radiation)
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7 pages, 204 KiB  
Article
Resonances in Systems Involving Positrons
by Anand K. Bhatia
Atoms 2020, 8(2), 20; https://doi.org/10.3390/atoms8020020 - 7 May 2020
Cited by 2 | Viewed by 2258
Abstract
When an incident particle on a target gets attached to the target, the cross-section at that energy could be much larger compared to those at other energies. This is a short-lived state and decays by emitting an electron. Such states can also be [...] Read more.
When an incident particle on a target gets attached to the target, the cross-section at that energy could be much larger compared to those at other energies. This is a short-lived state and decays by emitting an electron. Such states can also be formed by the absorption of a photon. Such states are below the higher thresholds and are called autoionization states, doubly excited states, or Feshbach resonances. There is also a possibility of such states to form above the thresholds. Then they are called shape resonances. Resonances are important in the diagnostic of solar and astrophysical plasmas. Some methods of calculating the resonance parameters are described and resonance parameters occurring in various systems are given. Full article
(This article belongs to the Special Issue Interactions of Positrons with Matter and Radiation)
13 pages, 549 KiB  
Article
Analytical Results for the Three-Body Radiative Attachment Rate Coefficient, with Application to the Positive Antihydrogen Ion H+
by Jack C. Straton
Atoms 2020, 8(2), 13; https://doi.org/10.3390/atoms8020013 - 20 Apr 2020
Cited by 1 | Viewed by 2260
Abstract
To overcome the numerical difficulties inherent in the Maxwell–Boltzmann integral of the velocity-weighted cross section that gives the radiative attachment rate coefficient α R A for producing the negative hydrogen ion H or its antimatter equivalent, the positive antihydrogen ion [...] Read more.
To overcome the numerical difficulties inherent in the Maxwell–Boltzmann integral of the velocity-weighted cross section that gives the radiative attachment rate coefficient α R A for producing the negative hydrogen ion H or its antimatter equivalent, the positive antihydrogen ion H ¯ + , we found the analytic form for this integral. This procedure is useful for temperatures below 700 K, the region for which the production of H ¯ + has potential use as an intermediate stage in the cooling of antihydrogen to ultra-cold (sub-mK) temperatures for spectroscopic studies and probing the gravitational interaction of the anti-atom. Our results, utilizing a 50-term explicitly correlated exponential wave function, confirm our prior numerical results. Full article
(This article belongs to the Special Issue Interactions of Positrons with Matter and Radiation)
7 pages, 669 KiB  
Article
Positron Impact Excitation of the nS States of Atomic Hydrogen
by Anand K. Bhatia
Atoms 2020, 8(1), 9; https://doi.org/10.3390/atoms8010009 - 3 Mar 2020
Cited by 3 | Viewed by 2399
Abstract
The excitation cross sections of the nS states, n = 2 to 6, of atomic hydrogen at various incident positron energies (10.23 to 300 eV) were calculated using the variational polarized-orbital method. Nine partial waves were used to obtain converged cross sections. The [...] Read more.
The excitation cross sections of the nS states, n = 2 to 6, of atomic hydrogen at various incident positron energies (10.23 to 300 eV) were calculated using the variational polarized-orbital method. Nine partial waves were used to obtain converged cross sections. The present results should be useful for comparison with results obtained from other theories and approximations. The positron-impact cross section was found to be higher than the electron-impact cross sections. Experimental and other theoretical results are discussed. The threshold law of excitation is discussed and the cross sections in this region were seen to obey the threshold law proportional to ( ln k f ) 2 . Cross sections were calculated in the Born approximation also and compared to those obtained using the variational polarized orbital method. Full article
(This article belongs to the Special Issue Interactions of Positrons with Matter and Radiation)
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10 pages, 1020 KiB  
Article
Calculations of Resonance Parameters for the Doubly Excited 1P° States in Ps Using Exponentially Correlated Wave Functions
by Sabyasachi Kar and Yew Kam Ho
Atoms 2020, 8(1), 1; https://doi.org/10.3390/atoms8010001 - 31 Dec 2019
Cited by 6 | Viewed by 2457
Abstract
Recent observations on resonance states of the positronium negative ion (Ps) in the laboratory created huge interest in terms of the calculation of the resonance parameters of the simple three-lepton system. We calculate the resonance parameters for the doubly excited 1 [...] Read more.
Recent observations on resonance states of the positronium negative ion (Ps) in the laboratory created huge interest in terms of the calculation of the resonance parameters of the simple three-lepton system. We calculate the resonance parameters for the doubly excited 1P° states in Ps using correlated exponential wave functions based on the complex-coordinate rotation method. The resonance energies and widths for the 1P° Feshbach resonance states in Ps below the N = 2, 3, 4, 5 Ps thresholds are reported. The 1P° shape resonance above the N = 2, 4 Ps thresholds are also reported. Our predications are in agreement with the available results. Few Feshbach resonance parameters below the N = 4 and 5 Ps thresholds have been reported in the literature. Our predictions will provide useful information for future resonance experiments in Ps. Full article
(This article belongs to the Special Issue Interactions of Positrons with Matter and Radiation)
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4 pages, 227 KiB  
Article
Photodetachment of the Positronium Negative Ion with Excitation in the Positronium Atom
by Anand K. Bhatia
Atoms 2019, 7(1), 2; https://doi.org/10.3390/atoms7010002 - 26 Dec 2018
Cited by 4 | Viewed by 2547
Abstract
Lyman-α radiation ( 2 P 1 S ) has been seen from astrophysical sources and the sun. The line shape of this transition has been measured recently in Ps atoms both inside and outside a porous silica target. In the photodetachment of [...] Read more.
Lyman-α radiation ( 2 P 1 S ) has been seen from astrophysical sources and the sun. The line shape of this transition has been measured recently in Ps atoms both inside and outside a porous silica target. In the photodetachment of Ps, the residual Ps atom can be left in the 2P state instead of the 1S state giving rise to positronium Lyman radiation at 2432 A0. Photodetachment cross sections of Ps have been calculated when the Ps atom is left in nP states, n being 2, 3, 4, 5, 6 and 7, using the asymptotic form of the bound-state wave function and a plane wave for the final state wave function, following the approach of Ohmura and Ohmura [Phys. Rev. 1960, 118, 154] in the photodetachment of H. Full article
(This article belongs to the Special Issue Interactions of Positrons with Matter and Radiation)
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Review

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30 pages, 1376 KiB  
Review
Positron Scattering from Atoms and Molecules
by Sultana N. Nahar and Bobby Antony
Atoms 2020, 8(2), 29; https://doi.org/10.3390/atoms8020029 - 15 Jun 2020
Cited by 8 | Viewed by 4001
Abstract
A review on the positron scattering from atoms and molecules is presented in this article. The focus on positron scattering studies is on the rise due to their presence in various fields and application of cross section data in such environments. Positron scattering [...] Read more.
A review on the positron scattering from atoms and molecules is presented in this article. The focus on positron scattering studies is on the rise due to their presence in various fields and application of cross section data in such environments. Positron scattering is usually investigated using theoretical approaches that are similar to those for electron scattering, being its anti-particle. However, most experimental or theoretical studies are limited to the investigation of electron and positron scattering from inert gases, single electron systems and simple or symmetric molecules. Optical potential and polarized orbital approaches are the widely used methods for investigating positron scattering from atoms. Close coupling approach has also been used for scattering from atoms, but for lighter targets with low energy projectiles. The theoretical approaches have been quite successful in predicting cross sections and agree reasonably well with experimental measurements. The comparison is generally good for electrons for both elastic and inelastic scatterings cross sections, while spin polarization has been critical due to its sensitive perturbing interaction. Positron scattering cross sections show relatively less features than that of electron scattering. The features of positron impact elastic scattering have been consistent with experiment, while total cross section requires significant improvement. For scattering from molecules, utilization of both spherical complex optical potential and R-matrix methods have proved to be efficient in predicting cross sections in their respective energy ranges. The results obtained shows reasonable comparison with most of the existing data, wherever available. In the present article we illustrate these findings with a list of comprehensive references to data sources, albeit not exhaustive. Full article
(This article belongs to the Special Issue Interactions of Positrons with Matter and Radiation)
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12 pages, 2551 KiB  
Review
Positron Processes in the Sun
by Nat Gopalswamy
Atoms 2020, 8(2), 14; https://doi.org/10.3390/atoms8020014 - 22 Apr 2020
Cited by 5 | Viewed by 4599
Abstract
Positrons play a major role in the emission of solar gamma-rays at energies from a few hundred keV to >1 GeV. Although the processes leading to positron production in the solar atmosphere are well known, the origin of the underlying energetic particles that [...] Read more.
Positrons play a major role in the emission of solar gamma-rays at energies from a few hundred keV to >1 GeV. Although the processes leading to positron production in the solar atmosphere are well known, the origin of the underlying energetic particles that interact with the ambient particles is poorly understood. With the aim of understanding the full gamma-ray spectrum of the Sun, I review the key emission mechanisms that contribute to the observed gamma-ray spectrum, focusing on the ones involving positrons. In particular, I review the processes involved in the 0.511 MeV positron annihilation line and the positronium continuum emissions at low energies, and the pion continuum emission at high energies in solar eruptions. It is thought that particles accelerated at the flare reconnection and at the shock driven by coronal mass ejections are responsible for the observed gamma-ray features. Based on some recent developments I suggest that energetic particles from both mechanisms may contribute to the observed gamma-ray spectrum in the impulsive phase, while the shock mechanism is responsible for the extended phase. Full article
(This article belongs to the Special Issue Interactions of Positrons with Matter and Radiation)
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4 pages, 178 KiB  
Review
A Precis of Threshold Laws for Positron vs. Electron Impact Ionization of Atoms
by A. Temkin
Atoms 2020, 8(2), 11; https://doi.org/10.3390/atoms8020011 - 10 Apr 2020
Viewed by 2090
Abstract
The Coulomb-dipole theory of positron vs. electron impact ionization of hydrogen (as a proxy for neutral atoms) is reviewed, emphasizing how the analytic form of the threshold law (but not the magnitude) can be the same, whereas the physics of each is entirely [...] Read more.
The Coulomb-dipole theory of positron vs. electron impact ionization of hydrogen (as a proxy for neutral atoms) is reviewed, emphasizing how the analytic form of the threshold law (but not the magnitude) can be the same, whereas the physics of each is entirely different. Full article
(This article belongs to the Special Issue Interactions of Positrons with Matter and Radiation)
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