Positron depth profiling in solid surface layers

Grynszpan, R.I.; Anwand, W.; Bräuer, G.; Coleman, P. G.

doi:10.3166/acsm.32.365-382

Cited by 9 publications

(6 citation statements)

References 46 publications

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“…1 presents a diagram that compares our knowledge of the sensitivity of positron annihilation techniques in defect studies to some other common measuring methods. Similar diagrams regarding methods and sensitivity limits have already been published before [9][10][11]. This diagram shows that positron techniques are most sensitive to very small defects, cover a large range of defect concentrations, and span the wider distribution of penetration depths, from the surface and deep into the bulk.…”

Section: Positrons As a Probe In Materials Researchsupporting

confidence: 56%

Investigations of HAVAR<sup>®</sup> Alloy Using Positrons

Beck¹,

Anwand

Wagner

et al. 2012

DDF

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A study of irradiation-induced damage in HAVAR® foils was initiated in order to extract the highest proton dose the foils can sustain. The lattice structure of HAVAR® foils in different metallurgic conditions is presented, as well as visible internal structure, measured by Transmission Electron Microscopy (TEM). Positron Annihilation Spectroscopy (PAS) techniques were used to investigate these foils, and another foil that had been irradiated to the maximal proton dose limit, set by the manufacturer to a total charge of 1 mAh (= 3.6 C). PAS techniques included Doppler broadening (DB) measurement in the SPONSOR beam and lifetime (LT) measurements, both carried at Helmholtz-Zentrum Dresden-Rossendorf (HZDR). Both positron spectroscopy methods show clear differences between the investigated foils, with distinguished characteristics for annealed, cold-rolled and irradiated foils. The advantages of using a slow positron beam to study thin foils and defect profiles, over a table-top LT spectrometer, are discussed and demonstrated by the HAVAR® measurements.

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Section: Positrons As a Probe In Materials Researchsupporting

confidence: 56%

Investigations of HAVAR<sup>®</sup> Alloy Using Positrons

Beck¹,

Anwand

Wagner

et al. 2012

DDF

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“…This source was always covered with two identically treated ZnO crystals thus forming a sandwich. The depth profile of the positrons in each sample exhibits a distribution which reaches a maximum at ∼43 µm and has a low intensity tail that extends as deep as ∼173 µm into ZnO 25. It has been estimated 3 that ∼90% of the positrons are annihilated within 100 µm of the surface, i.e., about 1/5 of the sample thickness.…”

Section: Methodsmentioning

confidence: 99%

Structural characterization of H plasma‐doped ZnO single crystals by positron annihilation spectroscopies

Anwand

Bräuer

Cowan

et al. 2010

Physica Status Solidi (a)

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Nominally undoped, hydrothermally grown ZnO single crystals have been investigated before and after exposure to remote H plasma. Structural characterizations have been made by various positron annihilation spectroscopies (continuous and pulsed slow positron beams, conventional lifetime). The content of bound hydrogen (H‐b) before and after the remote H plasma treatment at the polished side of the crystals was determined at depths of 100 and 600 nm, respectively, using nuclear reaction analysis. At a depth of 100 nm, H‐b increased from (11.8 ± 2.5) to (48.7 ± 7.6) × 1019 cm−3 after remote H plasma treatment, whereas at 600 nm no change in H‐b was observed.

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“…It is very encouraging to note that the slow positron tool increasingly finds its importance in studying subtle structural imperfections that could lead to crucial surface functional properties. It has also resulted in non-destructive depth profiling of defects in surfaces and interfaces [66] (depth selective from ~0.01 to 20 m).…”

Section: Defect and Diffusion Forum Vol 331mentioning

confidence: 99%

Positron Annihilation Spectroscopy: A Prelude to Modern Aspects

Ganguly

2012

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This article deals with the insight of using the positron (the simplest antimatter) as an entity that non-destructively probes material structure to the extent of atomic size defects, also describes the tools that have been in practice in recent times and in the front line activities. It also guides the reader on the use of (monoenergetic) slow positron beams that are currently available to study surface/ near surface structural details of various advanced materials. In addition, the bound state of electron and positron (positronium) is touched upon along with various conjectures for harnessing such species and utility of such light quasi-stationary states have been included. A brief mention has been made on the application of positrons towards medical diagnostic aspects and its recent importance in an astrophysical context.

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Positron depth profiling in solid surface layers

Cited by 9 publications

References 46 publications

Investigations of HAVAR<sup>®</sup> Alloy Using Positrons

Investigations of HAVAR<sup>®</sup> Alloy Using Positrons

Structural characterization of H plasma‐doped ZnO single crystals by positron annihilation spectroscopies

Positron Annihilation Spectroscopy: A Prelude to Modern Aspects

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