Antihydrogen accumulation for fundamental symmetry tests

Ahmadi, Mostafa; Alves, B. X. R.; Baker, CJ; Bertsche, W.; Butler, E.; Capra, A.; Carruth, C.; Cesar, C. L.; Charlton, M.; Cohen, Seymour S.; Collister, R.; Eriksson, S.; Evans, Ally J.; Evetts, N.; Fajans, J.; Friesen, T.; Fujiwara, M.; Gill, D. R.; Gutiérrez, A.; Hangst, J. S.; Hardy, W. N.; Hayden, M. E.; Isaac, C. A.; Ishida, Akira; Johnson, M. A.; Jones, S. A.; Jonsell, Svante; Kurchaninov, L. L.; Madsen, N.; Mathers, M.; Maxwell, D.; McKenna, J. T. K.; Menary, S.; Michan, J. M.; Momose, Takamasa; Munich, J. J.; Nolan, P.; Olchanski, K.; Olin, Å.; Pusa, P.; Rasmussen, C. Ø.; Robicheaux, F.; Sacramento, R. L.; Sameed, M.; Sarid, E.; Silveira, D. M.; Stracka, S.; Stutter, G.; So, C.; Tharp, T. D.; Thompson, John E.; Thompson, R. I.; Werf, D. P. van der; Wurtele, J. S.

doi:10.1038/s41467-017-00760-9

Cited by 69 publications

(61 citation statements)

References 30 publications

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“…Presently, there is considerable interest in the antihydrogen trapping community to use beryllium ions to sympathetically cool positrons for antihydrogen production [18][19][20][21]. The antihydrogen trapping experiments take place in a Penning trap under extreme high vacuum (P<10 −12 mbar) and cryogenic temperatures (T<100 K).…”

Section: Introductionmentioning

confidence: 99%

Ion generation and loading of a Penning trap using pulsed laser ablation

2020

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We investigated the production of aluminum and beryllium ions via pulsed laser ablation using 355 nm wavelength and 5 ns long laser pulses. The ablation threshold of Al + and Be + was measured to be 0.9±0.1 (stat.)±0.3 (syst.) J cm −2 and 1.4±0.1(stat.)±0.4 (syst.) J cm −2 respectively. By employing electrostatic retarding potentials, the kinetic energy profile of the ablated ions was characterized as a function of laser fluence. Around the ablation threshold, we reliably produced between 10 8 and 10 10 ions, approximately 5% of which were dynamically trapped in a Penning-Malmberg trap.

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Section: Introductionmentioning

confidence: 99%

Ion generation and loading of a Penning trap using pulsed laser ablation

2020

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“…Finally, we make a comparison of our results with experimentally observed trapping fractions. In a recent publication by ALPHA [18],H formation at T=18 K and n e =6.5×10 13 m −3 (at the beginning of the mixing with antiprotons) resulted in,  f 0.4 H and f trap ;10 −4 . For similar conditions our results give  f 0.5 H and f trap ;10 −3 , and further multiplication of f trap by 0.13 (to account for the trap depth of 2 K in the simulations, compared to 0.5 K in the experiment) reduces this number to 1.3×10 −4 .…”

Section: Resultsmentioning

confidence: 97%

“…Techniques such as evaporative [14] and adiabatic [15] cooling have been developed, whilst compression techniques (see, e.g., [16,17]) have allowed the density and radial extent of the clouds to be carefully manipulated. Whilst this has led to marked improvements inH trapping efficiencies (here, defined as the number ofH trapped per injectedp), from about 5×10 −6 in the earliest work [10] to over 10 −4 in a recent study [18], it is clear that many measurements will benefit markedly from increases in the yield of trappedH.…”

Section: Introductionmentioning

confidence: 99%

On the formation of trappable antihydrogen

Jonsell

Charlton

2018

New J. Phys.

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The formation of antihydrogen atoms from antiprotons injected into a positron plasma is simulated, focussing on the fraction that fulfil the conditions necessary for confinement of anti-atoms in a magnetic minimum trap. Trapping fractions of around 10 −4 are found under conditions similar to those used in recent experiments, and in reasonable accord with their results. We have studied the behaviour of the trapped fraction at various positron plasma densities and temperatures and found that collisional effects play a beneficial role via a redistribution of the antihydrogen magnetic moment, allowing enhancements of the yield of low-field seeking states that are amenable to trapping.

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“…These, and other, advances were made possible by the confinement of H in magnetic minimum traps [4][5][6]. Recently, these techniques have been improved at CERN's antiproton decelerator (AD) [7] such that about 10-20 H s can be trapped per antiproton (p) bunch, and through the accumulation of H s from successive bunches [8] several hundred H s can be held simultaneously [2].…”

Section: Introductionmentioning

confidence: 99%

Formation of antihydrogen beams from positron–antiproton interactions

Jonsell

Charlton

2019

New J. Phys.

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The formation of a beam of antihydrogen atoms when antiprotons pass through cold, dense positron plasmas is simulated for various plasma properties and antiproton injection energies. There are marked dependences of the fraction of injected antiprotons which are emitted as antihydrogen in a beam-like configuration upon the temperature of the positrons, and upon the antiproton kinetic energy. Yields as high as 13% are found at the lowest positron temperatures simulated here (5 K) and at antiproton kinetic energies below about 0.1 eV. By 1 eV the best yields are as low as 10 −3 , falling by about two orders of magnitude with an increase of the positron temperature to 50 K. Example distributions for the antihydrogen angular emission, binding energy and kinetic energy are presented and discussed. Comparison is made with experimental information, where possible.

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Antihydrogen accumulation for fundamental symmetry tests

Cited by 69 publications

References 30 publications

Ion generation and loading of a Penning trap using pulsed laser ablation

Ion generation and loading of a Penning trap using pulsed laser ablation

On the formation of trappable antihydrogen

Formation of antihydrogen beams from positron–antiproton interactions

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