Low-energy positron interactions with krypton

Makochekanwa, Casten; Machacek, Joshua; Jones, Adric; Caradonna, Peter; Slaughter, Daniel; McEachran, R P; Sullivan, James P.; Buckman, Stephen; Bellm, Susan; Lohmann, Birgit; Fursa, Dmitry V.; Bray, Igor; Mueller, D.; Stauffer, A D; Hoshino, M.

doi:10.1103/physreva.83.032721

Cited by 39 publications

(63 citation statements)

References 45 publications

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“…Indeed, the discrepancy is nearly 35% at about 20 eV. We were a little surprised by this result, as previous studies by the two groups on argon, 41,71 krypton, 42,72 and xenon 73,74 had shown a quite satisfactory level of accord between their "uncorrected" TCS. Indeed, Zecca et al 69 noted that the angular discrimination of the Trento apparatus is comparable to that of the present spectrometer and since both independent measurements were conducted at the same temperature (∼24 ± 2…”

Section: A Total Cross Sectionsmentioning

confidence: 61%

“…The methods used in the present experiment to measure those cross sections have already been described earlier by Makochekanwa et al, 42 Caradonna et al, 47 and Sullivan et al 43 We briefly summarize them here, by recalling that those measurements require an alteration to the experimental technique from that used in the case of quasi-elastic scattering.…”

Section: Methodsmentioning

confidence: 99%

“…It is worth noting here that in our experimental technique positrons scattered in the backward direction (i.e., through angles greater than 90 • ) are reflected from the potential barriers associated with the trap and other elements, and can travel back through the gas cell. 42,43 As a result, the measured cross section at any angle θ is actually folded about 90…”

Section: Elastic Differential Cross Sectionsmentioning

confidence: 99%

“…The techniques used in the present experiment to measure the TCS, the Ps formation cross sections, the elastic DCS, and the details of the data analysis, have been presented previously. [41][42][43] In short, the various cross sections are determined by measuring specific fractions of the positron beam transmitted through the RPA with the target vapor present in the scattering cell. In a collision with a target molecule, the positron can be elastically scattered through some angle θ and lose some of its E in the process.…”

Section: Methodsmentioning

confidence: 99%

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Total, elastic, and inelastic cross sections for positron and electron collisions with tetrahydrofuran

Chiari

Anderson

Tattersall

et al. 2013

The Journal of Chemical Physics

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We present total, elastic, and inelastic cross sections for positron and electron scattering from tetrahydrofuran (THF) in the energy range between 1 and 5000 eV. Total cross sections (TCS), positronium formation cross sections, the summed inelastic integral cross sections (ICS) for electronic excitations and direct ionization, as well as elastic differential cross sections (DCS) at selected incident energies, have been measured for positron collisions with THF. The positron beam used to carry out these experiments had an energy resolution in the range 40-100 meV (full-width at half-maximum). We also present TCS results for positron and electron scattering from THF computed within the independent atom model using the screening corrected additivity rule approach. In addition, we calculated positron-impact elastic DCS and the sum over all inelastic ICS (except rotations and vibrations). While our integral and differential positron cross sections are the first of their kind, we compare our TCS with previous literature values for this species. We also provide a comparison between positron and electron-impact cross sections, in order to uncover any differences or similarities in the scattering dynamics with these two different projectiles.

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Section: A Total Cross Sectionsmentioning

confidence: 61%

Section: Methodsmentioning

confidence: 99%

Section: Elastic Differential Cross Sectionsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

See 2 more Smart Citations

Total, elastic, and inelastic cross sections for positron and electron collisions with tetrahydrofuran

Chiari

Anderson

Tattersall

et al. 2013

The Journal of Chemical Physics

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“…Japanese positron beam in Tsukuba continues to challenge important questions, mainly in the fi eld of semiconductors [43]. The beam constructed within a national programme at the Australian National University in Canberra is dedicated mainly to atomic physics [44]. Currently operating positron beams, among others, in Helsinki [45], Halle [46], London [47], Delft [48], and Orleans [49] rarely go beyond national contexts and specialized applications, with the exception of the NEPOMUC facility, where scientists of European countries have access within the EU great facilities NI3 programme.…”

Section: Toward a European Networkmentioning

confidence: 99%

Toward a European Network of Positron Laboratories

et al. 2015

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Positron defectoscopyPositron annihilation is one of the few really nondestructive techniques in material science, giving unique information on types and concentrations of defects, even at a single parts per million (ppm) level, see, for example, [1]. Applications of positron annihilation techniques span from semiconductors [2,3] and metals [4] to polymers [5] and porous media [6]. In each case, answers given by positron methods are unique and complementary to other techniques.Two most common techniques, the analysis of Doppler broadening (DB) of the 511-keV annihilation line and the positron lifetime measurements, are to some extent complementary. The broadening brings information on momenta of electrons that positrons annihilate with. The main contribution to the annihilation comes from valence electrons, that is, possessing a few electron-volts energy. In the relativistic transformation, these energies translate to broadening of a few kiloelectron-volts, i.e. similar to the intrinsic resolution of gamma detectors used in experiments. Therefore, the information on relative contributions from valence and core (i.e., from defect sites) electrons is not straightforward. Somewhat phenomenological line-broadening parameters (central area S parameter, W lateral area, V 3 annihilation) are used, and some normalization is needed to make comparison between different experiments and theories. Evaluation of DB requires not only information of the overlap between a positron and electrons in the material but also a detailed

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