Laser cooling of antihydrogen atoms

Baker, C.J.; Bertsche, W.; Capra, A.; Carruth, C.; Cesar, C. L.; Charlton, M.; Christensen, Andrew; Collister, R.; Mathad, A. Cridland; Eriksson, S.; Evans, Ally J.; Evetts, N.; Fajans, J.; Friesen, T.; Fujiwara, M.; Gill, D. R.; Grandemange, P.; Granum, P.; Hangst, J. S.; Hardy, W. N.; Hayden, M. E.; Hodgkinson, D.; Hunter, E. D.; Isaac, C. A.; Johnson, M. A.; Jones, Jimmy; Jones, S. A.; Jonsell, Svante; Khramov, Alexander; Knapp, Patrick; Kurchaninov, L. L.; Madsen, N.; Maxwell, D.; McKenna, J. T. K.; Menary, S.; Michan, J. M.; Momose, Takamasa; Mullan, P. S.; Munich, J. J.; Olchanski, K.; Olin, Å.; Peszka, J.; Powell, Adam; Pusa, P.; Rasmussen, C. Ø.; Robicheaux, F.; Sacramento, R. L.; Sameed, M.; Sarid, E.; Silveira, D. M.; Starko, Darij Markian; So, C.; Stutter, G.; Tharp, T. D.; Thibeault, A. H.; Thompson, R. I.; Werf, D. P. van der; Wurtele, J. S.

doi:10.1038/s41586-021-03289-6

Cited by 52 publications

(35 citation statements)

References 61 publications

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“…The ALPHA experiment roughly goes as follows (ALPHA Collaboration, 2011, Figure 1) and (Baker et al, 2021, Figure 1). Using CERN's antiproton and positron accelerators and decelerators, soft antiproton and positron beams are injected into a tube of 280 mm axial length and of 44.35 mm diameter.…”

Section: δS(s ) ∶= S(s ( + )) − S(s ( ))mentioning

confidence: 96%

“…However after taking an overview of these efforts we can select for our purposes the most relevant one namely the ALPHA experiment at CERN, which is a very exciting ongoing experiment exhibiting lot of new (but on theoretical grounds expected) facts about antihydrogen atoms, to see whether or not the communicated results can be used to support or reject the Proposal. Latest results have been reported in Baker et al (2021) however from our point of view, i.e. regarding some technical background details, we shall revisit an older paper ALPHA Collaboration (2011) from 2011 too.…”

Section: δS(s ) ∶= S(s ( + )) − S(s ( ))mentioning

confidence: 99%

“…Thus of course this environment consists of ordinary matter having standard thermodynamical properties. What from our viewpoint relevant is the values of the following three parameters in every individual attempt or run of the experiment: the number N of trapped antihydrogen atoms, their temperature T and their confinement time t. Although the cumulative value of N was reported to be about 1000 in ALPHA Collaboration (2011); Baker et al (2021), its average value in individual attempts (i.e. the situation when antiatoms are under sharp observational control), as summarized in (ALPHA Collaboration, 2011, Table 1 and Figure 2) (but not available in Baker et al, 2021), was N ≈ 1 .…”

Section: δS(s ) ∶= S(s ( + )) − S(s ( ))mentioning

confidence: 99%

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Primordial Black Holes from Collapsing Antimatter

Etesi

2022

Found Sci

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In this paper a simple (i.e. free of fine-tuning, etc.) new mechanism for primordial black hole formation based on the collapse of large antimatter systems in the early Universe is introduced. A peculiarity of this process is that, compared to their material counterparts, the collapse of large antimatter systems takes much less time due to the reversed thermodynamics of antimatter, an idea which has been proposed in our earlier paper Etesi (2021). This model has several testable predictions. The first is that the photon-baryon ratio is roughly computable and is equal to $$3.03\times 10^9$$ 3.03 × 10 9 which is quite close to its experimentally confirmed value. The second is that the mass of black holes arising from this mechanism is at least $$10^5$$ 10 5 -$$10^6M_\odot$$ 10 6 M ⊙ hence they contribute to the super- or hypermassive end of the primordial black hole mass spectrum. The third prediction is that these sort of primordial black holes constitute at least $$20\%$$ 20 % of dark matter. Last but not least the observed current asymmetry of matter and antimatter, even if their presence in the Universe was symmetric in the beginning, acquires a natural explanation, too.

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Section: δS(s ) ∶= S(s ( + )) − S(s ( ))mentioning

confidence: 96%

Section: δS(s ) ∶= S(s ( + )) − S(s ( ))mentioning

confidence: 99%

Section: δS(s ) ∶= S(s ( + )) − S(s ( ))mentioning

confidence: 99%

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Primordial Black Holes from Collapsing Antimatter

Etesi

2022

Found Sci

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“…As a part of this development, one has to note the remarkable improvement constituted by the first extension of the laser cooling technique to antimatter. This was obtained by the ALPHA collaboration by making use of the 1S-2P dipole-allowed transition and the Lyman-α laser system developed on purpose [48]. Meanwhile, the laser system performs cooling along a specific direction (symmetry axis of the apparatus, see Figure 4a) and the confining effect of the traps couples the spatial degrees of freedom so that overall cooling is demonstrated.…”

Section: The Beginning Of Anti-hydrogen Spectroscopymentioning

confidence: 99%

Low Energy Antimatter Physics

Giammarchi

Vinelli

2022

Universe

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“…By comparing it to antihydrogen, hydrogen can be used to test matter-antimatter symmetries with high precision [8]. In the last 10 years, antihydrogen physics has advanced to the point where more than 1000 atoms can be simultaneously trapped [9], cooled [10], and probed with lasers [11,12] and microwaves [13]. The field is rapidly approaching hydrogen-like precision, and hydrogen-antihydrogen comparisons may soon encounter the same class of hard-to-characterise systematic effects that lead to discrepancies when different groups using different techniques try to measure the same parameters, as demonstrated by the aforementioned proton radius puzzle.…”

Section: Introductionmentioning

confidence: 99%

An ion trap source of cold atomic hydrogen via photodissociation of the BaH⁺ molecular ion

Jones

2022

New J. Phys.

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I present a novel scheme for producing cold (magnetically trappable) atomic hydrogen, based on threshold photodissociation of the BaH+ molecular ion. BaH+ can be sympathetically cooled using laser cooled Ba+ in an ion trap, before it is photodissociated on the single photon A1Σ+←X1Σ+ transition. The small mass ratio between Ba+ and BaH+ ensures a strong overlap within the ion trap for sympathetic cooling, whilst the large mass ratio between BaH+ and H means that the released hydrogen can be up to 139 times colder than the parent molecular ions. I examine the hydrogen production rate, and describe how the trap dynamics and photodissociation laser detuning influence the achievable energies. The low infrastructure costs and the ion trap nature of the scheme make it suitable for loading hydrogen into an antihydrogen experiment. This would support a direct matter-antimatter comparison, which could provide important clues as to why our universe contains so little antimatter.

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Laser cooling of antihydrogen atoms

Cited by 52 publications

References 61 publications

Primordial Black Holes from Collapsing Antimatter

Primordial Black Holes from Collapsing Antimatter

Low Energy Antimatter Physics

An ion trap source of cold atomic hydrogen via photodissociation of the BaH⁺ molecular ion

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Laser cooling of antihydrogen atoms

Cited by 52 publications

References 61 publications

Primordial Black Holes from Collapsing Antimatter

Primordial Black Holes from Collapsing Antimatter

Low Energy Antimatter Physics

An ion trap source of cold atomic hydrogen via photodissociation of the BaH+ molecular ion

Contact Info

Product

Resources

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An ion trap source of cold atomic hydrogen via photodissociation of the BaH⁺ molecular ion