Muon capture on deuteron and the neutron-neutron scattering length

Abstract

We study the capture rate in the doublet hyperfine initial state for the muon capture reaction μ- + \,2 H → μ + n + n (D) and the total capture rate for the reaction μ- + \,3 He → μ + \,3 H (0). We investigate whether D and 0 could be sensitive to the nn S-wave scattering length (ann). To this aim, we consider nuclear potentials and weak currents derived within . We employ the N3LO chiral potential with cutoff =500 MeV, but the low-energy constant (LEC) determining ann is varied so as to obtain ann=-18.95 (the present empirical value), -16.0, -22.0, and +18.22 fm. The last value leads to a nn bound state with a binding energy of 139 keV. The LECs cD and cE, present in the three-nucleon potential and axial-vector current, are fitted to reproduce the A=3 binding energies and the triton Gamow-Teller matrix element. The capture rate D is found to be 399(3) s-1 for ann=-18.95 and -16.0 fm; and 400(3) s-1 for ann=-22.0 fm. For ann=+18.22 fm, we obtain 275(3) s-1 (135(3) s-1), when the final nn system is unbound (bound). The rate 0 is found to be 1494(15), 1491(16), 1488(18), and 1475(16) s-1 for ann=-18.95, -16.0, -22.0, and +18.22 fm, respectively. The theoretical uncertainties are due to the fitting procedure and radiative corrections. Our results seem to exclude the possibility of constraining a negative ann with an uncertainty of less than 3 fm through an accurate determination of the muon capture rates, but the uncertainty on the present empirical value will not complicate the interpretation of the (forth-coming) experimental results for D. Finally, a comparison with the already available experimental data discourages the possibility of a bound nn state.