The measurement of the 99Tc β-decay spectrum and its implications for the effective value of weak axial coupling

Abstract

Measurements of β-spectral shapes is an important way to examine the effective value of the weak axial coupling g A. These stu\ dies focus specifically on forbidden non-unique β- transitions, as only in these cases is the spectral shape directly sensitive to th\ e ratio g A/g V. Here, the value of the weak vector coupling constant, g V, is fixed at 1.0 according to the Conserve\ d Vector Current (CVC) hypothesis. In previous studies for the fourth-forbidden non-unique β- decays of 113Cd [J.~Kostensalo et al., Phys. Lett. B 822, 136652 (2021)] and 115In [A.~F. Leder et al., Phys. Rev. Lett. 129, 232502 \ (2022) and L. Pagnanini et al., Phys. Rev. Lett. 133, 122501 (2024)] a quenched value was determined for the ratio g A/g V using g V=1.0. A notable exception is the recent measurement and analysis of the second-forbidden non-unique \ β-decay transition in 99Tc, performed by M. Paulsen et al., Phys. Rev. C 110, 05503(2024). Where an enhanced ratio g\\ rm A/g V=1.526(92) was suggested. To resolve this apparently contradictory situation with the effective value of g A, we hav\ e performed calculations based on the nuclear shell model (NSM) Hamiltonians glekpn, jj45pnb, and the MQPM approach with a careful considera\ tion of the small relativistic vector nuclear matrix element (sNME). The theoretical spectra were compared to the 99Tc β-decay sp\ ectrum by using the 4π gold absorber with a Metallic Magnetic Calorimeter (MMC). In all cases, we found that the data matches well with \ reduced g A/g V values of 1.0--1.2. Our result contradicts the previously reported measurement for 99Tc and instead sup\ ports a quenched axial coupling as reported for other isotopes.