2010
DOI: 10.1103/physrevlett.104.243401
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Positronium Cooling and Emission in Vacuum from Nanochannels at Cryogenic Temperature

Abstract: High formation yield and a meaningful cooled fraction of positronium below room temperature were obtained by implanting positrons in a silicon target in which well-controlled oxidized nanochannels (5-8 nm in diameter) perpendicular to the surface were produced. We show that by implanting positrons at 7 keV in the target held at 150 K, about 27% of positrons form positronium that escapes into the vacuum. Around 9% of the escaped positronium is cooled by collision with the walls of nanochannels and is emitted wi… Show more

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Cited by 107 publications
(108 citation statements)
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“…Other elemental and compound semiconductors that have dangling bond states should produce Ps via the same basic mechanism, and by varying their properties it may be possible to adjust the Ps energy. An efficient source of cold Ps that may be used in a low temperature environment, and that allows for the production of short-time bursts of positronium atoms [77] could have numerous experimental applications, including direct Ps gravity measurements [78], the formation of antihydrogen atoms via Ps-antiproton interactions [79], Psatom scattering [7], loading a stellerator to study electronpositron plasmas [80], the production of positron-atom bound states [81] and precision laser spectroscopy [4,82]. Any type of experiment involving Ps-laser interactions would benefit from an efficient source of monoenergetic Ps, since the Doppler spread of these light atoms (~ 500 GHz for thermal Ps) is in general much larger than typical laser bandwidths and is the limiting factor in the excitation efficiency.…”
Section: Discussionmentioning
confidence: 99%
“…Other elemental and compound semiconductors that have dangling bond states should produce Ps via the same basic mechanism, and by varying their properties it may be possible to adjust the Ps energy. An efficient source of cold Ps that may be used in a low temperature environment, and that allows for the production of short-time bursts of positronium atoms [77] could have numerous experimental applications, including direct Ps gravity measurements [78], the formation of antihydrogen atoms via Ps-antiproton interactions [79], Psatom scattering [7], loading a stellerator to study electronpositron plasmas [80], the production of positron-atom bound states [81] and precision laser spectroscopy [4,82]. Any type of experiment involving Ps-laser interactions would benefit from an efficient source of monoenergetic Ps, since the Doppler spread of these light atoms (~ 500 GHz for thermal Ps) is in general much larger than typical laser bandwidths and is the limiting factor in the excitation efficiency.…”
Section: Discussionmentioning
confidence: 99%
“…In the target, e + were efficiently converted into o-Ps and emitted into vacuum [35,36]. A calibrated CsI detector and a microchannel plate (MCP) with a phosphor screen, set in place of the target, were used to characterize the number and the spot dimension of positrons impinging on the target.…”
Section: Experimental Methodsmentioning
confidence: 99%
“…1. A bunch of positrons impinging on a Si target with oriented oxidized nanochannels [22,23] produced copious Ps emission in vacuum. Ps excitation was measured by means of the single shot positron annihilation lifetime spectroscopy (SSPALS) technique [24].…”
Section: Positron Confinement Ps Formation and Excitationmentioning
confidence: 99%