Beta-neutrino correlation experiments on laser trapped 38mK, 37K

A. Gorelov, J. A. Behr, D. Melconian, M. Trinczek, P. Dubé, O. Häusser, U. Giesen, K. P. Jackson, T. Swanson, J. M. D'Auria, M. Dombsky, G. Ball, L. Buchmann, B. Jennings, J. Dilling, J. Schmid, D. Ashery, J. Deutsch, W. P. Alford, D. AsgeirssonW. Wong, B. Lee

Research output: Contribution to journalArticlepeer-review

33 Scopus citations

Abstract

Laser trapping and cooling techniques are now being applied to the study of nuclear β-decay at several labs. A magneto-optical trap (MOT) provides a localized source of atoms suspended in space, so the low-energy recoiling nuclei can freely escape and be detected in coincidence with the β. This allows reconstruction of the neutrino momentum, and the deduction of the β-ν correlation in a more direct fashion than previously possible. In addition, the nuclei can be polarized by atomic techniques, opening a new class of spin-correlation measurements to test the degree to which parity is maximally violated in the weak interaction. Our present experiment has detected several hundred thousand recoil-β+ coincidences from the 0+ → 0+ pure Fermi decay of 38mK, produced at the on-line isotope separators TISOL and ISAC at TRIUMF. Our goal is to set constraints on non-Standard Model scalar bosons competitive with high-energy colliders and more conventional β-ν correlation experiments.

Original languageEnglish
Pages (from-to)373-380
Number of pages8
JournalHyperfine Interactions
Volume127
Issue number1-4
DOIs
StatePublished - 2000
Externally publishedYes

Keywords

  • Beta decay
  • Charge state
  • Neutral atom trap
  • Shakeoff electron

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