Decay study of $^{11}$Be with an Optical TPC detector

TL;DR

This study investigates the beta decay of the one-neutron halo nucleus $^{11}$Be using an Optical TPC detector, measuring beta-delayed charged particles and analyzing the decay spectrum within an R-matrix framework.

Contribution

It provides new experimental measurements of beta-delayed alpha emission and sets limits on beta-delayed proton emission using advanced detection techniques.

Findings

Beta-delayed alpha emission branching ratio: 3.27(46)%

Energy spectrum consistent with literature and R-matrix analysis

Upper limit for beta-delayed proton emission: (2.2 ± 0.6_stat ± 0.6_sys) × 10^{-6}

Abstract

The $\beta$ decay of one-neutron halo nucleus $^{11}$Be was investigated using the Warsaw Optical Time Projection Chamber (OTPC) detector to measure $\beta$-delayed charged particles. The results of two experiments are reported. In the first one, carried out in LNS Catania, the absolute branching ratio for $\beta$-delayed $\alpha$ emission was measured by counting incoming $^{11}$Be ions stopped in the detector and the observed decays with the emission of $\alpha$ particle. The result of 3.27(46)\% is in good agreement with the literature value. In the second experiment, performed at the HIE-ISOLDE facility at CERN, bunches containing several hundreds of $^{11}$Be ions were implanted into the OTPC detector followed by the detection of decays with the emission of charged particles. The energy spectrum of $\beta$-delayed $\alpha$ particles was determined in the full energy range. It was analysed in the R-matrix framework and was found to be consistent with the literature. The best description of the spectrum was obtained assuming that the two $3/2^+$ and one $1/2^+$ states in $^{11}$B are involved in the transition. The search for $\beta$-delayed emission of protons was undertaken. Only the upper limit for the branching ratio for this process of $(2.2 \pm 0.6_{\rm stat} \pm 0.6_{\rm sys}) \times 10^{-6}$ could be determined. This value is in conflict with the result published in [Ayyad et al. Phys. Rev. Lett. 123, 082501 (2019)] but does agree with the limit reported in [Riisager et al., Eur. Phys. J. A (2020) 56:100]