English

Neutron Lifetime and Axial Coupling Connection

High Energy Physics - Phenomenology 2018-05-23 v3

Abstract

Experimental studies of neutron decay, npeνˉn\to pe\bar\nu, exhibit two anomalies. The first is a 8.6(2.1)s, roughly 4σ4\sigma difference between the average beam measured neutron lifetime, τnbeam=888.0(2.0)\tau_n^\text{beam}=888.0(2.0)s, and the more precise average trapped ultra cold neutron determination, τntrap=879.4(6)\tau_n^\text{trap}=879.4(6)s. The second is a 5σ5\sigma difference between the pre2002 average axial coupling, gAg_A, as measured in neutron decay asymmetries gApre2002=1.2637(21)g_A^\text{pre2002}=1.2637(21), and the more recent, post2002, average gApost2002=1.2755(11)g_A^\text{post2002}=1.2755(11), where, following the UCNA collaboration division, experiments are classified by the date of their most recent result. In this study, we correlate those τn\tau_n and gAg_A values using a (slightly) updated relation τn(1+3gA2)=5172.0(1.1)\tau_n(1+3g_A^2)=5172.0(1.1)s. Consistency with that relation and better precision suggest τnfavored=879.4(6)\tau_n^\text{favored}=879.4(6)s and gAfavored=1.2755(11)g_A^\text{favored}=1.2755(11) as preferred values for those parameters. Comparisons of gAfavoredg_A^\text{favored} with recent lattice QCD and muonic hydrogen capture results are made. A general constraint on exotic neutron decay branching ratios, <0.27%<0.27\%, is discussed and applied to a recently proposed solution to the neutron lifetime puzzle.

Keywords

Cite

@article{arxiv.1802.01804,
  title  = {Neutron Lifetime and Axial Coupling Connection},
  author = {Andrzej Czarnecki and William J. Marciano and Alberto Sirlin},
  journal= {arXiv preprint arXiv:1802.01804},
  year   = {2018}
}
R2 v1 2026-06-23T00:12:30.145Z