Dynamics of magnetic evaporative beamline cooling for the preparation of cold atomic beams
Project 8 Collaboration; Ashtari Esfahani, A.; Bhagvati, S.; Böser, S.; Brandsema, M. J.; Cabral, R.; Chirayath, V. A.; Claessens, C.; Coward, N.; de Viveiros, L.; Doe, P. J.; Elliott, M. G.; Enomoto, S.; Fertl, M.; Formaggio, J. A.; Foust, B. T.; Gaison, J. K.; Harmston, P.; Heeger, K. M.;
Abstract (englisch):
The most sensitive direct neutrino mass searches today are based on measurement of the end point of the 𝛽
spectrum of tritium to infer limits on the mass of the unobserved neutrino. To avoid the smearing associated with the distribution of molecular final states in the T-He molecule, the next generation of these experiments will need to employ atomic (T) rather than molecular (T$_2$) tritium sources, at currents of at least 10$^{15}$ atoms per second. Following production, atomic T can be trapped in gravitational and/or magnetic bottles for 𝛽 spectrum experiments, if and only if it can first be cooled to millikelvin temperatures. Accomplishing this cooling presents substantial technological challenges. The Project 8 collaboration is developing a technique based on magnetic evaporative cooling along a beamline (MECB) for the purpose of cooling T to feed a magnetogravitational trap that also serves as a cyclotron radiation emission spectroscope. Initial tests of the approach are planned in a pathfinder apparatus using atomic Li. This paper presents a method for analyzing the dynamics of the MECB technique and applies these calculations to the design of systems for cooling and slowing of atomic Li and T. ... mehr
spectrum of tritium to infer limits on the mass of the unobserved neutrino. To avoid the smearing associated with the distribution of molecular final states in the T-He molecule, the next generation of these experiments will need to employ atomic (T) rather than molecular (T$_2$) tritium sources, at currents of at least 10$^{15}$ atoms per second. Following production, atomic T can be trapped in gravitational and/or magnetic bottles for 𝛽 spectrum experiments, if and only if it can first be cooled to millikelvin temperatures. Accomplishing this cooling presents substantial technological challenges. The Project 8 collaboration is developing a technique based on magnetic evaporative cooling along a beamline (MECB) for the purpose of cooling T to feed a magnetogravitational trap that also serves as a cyclotron radiation emission spectroscope. Initial tests of the approach are planned in a pathfinder apparatus using atomic Li. This paper presents a method for analyzing the dynamics of the MECB technique and applies these calculations to the design of systems for cooling and slowing of atomic Li and T. ... mehr
| Zugehörige Institution(en) am KIT | Institut für Astroteilchenphysik (IAP) |
| Publikationstyp | Zeitschriftenaufsatz |
| Publikationsmonat/-jahr | 09.2025 |
| Sprache | Englisch |
| Identifikator | ISSN: 2469-9926, 2469-9934 KITopen-ID: 1000188735 |
| Erschienen in | Physical Review A |
| Verlag | American Physical Society (APS) |
| Band | 112 |
| Heft | 3 |
| Seiten | 033311 |
| Vorab online veröffentlicht am | 11.09.2025 |
| Schlagwörter | Atom & ion cooling, Atom & ion trapping & guiding, Atom optics, Beam code development & simulation techniques, Beam optics, Beta decay, Cold and ultracold molecules, Ultracold collisions, Neutrinos, Neutrino mass |
| Nachgewiesen in | Scopus OpenAlex Dimensions Web of Science |