Abstract
An observation of neutron–antineutron oscillations would constitute a discovery of fundamental importance for particle physics and cosmology. The required change in baryon number and lepton number ( Δ B = 2 , Δ L = 0 ) relates neutron–antineutron oscillations to neutrinoless double beta decay ( Δ B = 0 , Δ L = 2 ) and the physics of B – L symmetry breaking and neutrino mass generation in several theories beyond the Standard Model which unify quarks and leptons. Recent theoretical models which posit new energy scales for B–L symmetry breaking in the ranges from 10 5 to 10 11 GeV can produce neutron–antineutron oscillations close to the existing limits. We mention recent developments in cold and ultracold neutron technology which can make possible improvements in the sensitivity to the free neutron oscillation probability by factors from ≈ 100 to 1000 . For these sensitivities a null result would place the most stringent limit on this possible mode of matter instability.
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Schedule a callMore From: Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment
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