Ab initio correlations between neutrinoless and two-neutrino double-beta decays in 48Ca

Abstract

We develop a novel ab initio in-medium no-core configuration-interaction (IM-NCCI) framework for nuclear charge-exchange processes by combining the in-medium similarity renormalization group with chiral nuclear Hamiltonians, and apply it to the 2νββ and 0νββ decays of 48Ca. This framework reproduces the locations of several main resonance peaks in the Gamow-Teller (GT) strength distribution for the 48Ca48Sc transition. The cumulative GT strength indicates missing contributions from two-body weak currents, corresponding to an effective quenching factor of q0.84. Incorporating this quenching yields a 2νββ nuclear matrix element (NME) in excellent agreement with experiment. Applying the same framework to 0νββ decay, and including the contribution from short-range operators, we obtain a total NME of M0ν=1.00-2.02. Using 34 non-implausible chiral Hamiltonians, we establish from first principles strong linear correlations between the 0νββ NME and the NMEs governing 2νββ decay and double GT transitions. Combining these correlation relations within the 95% confidence level with the experimental 2νββ-decay data yields a constrained prediction of M0ν=1.30-1.65. This work establishes IM-NCCI as a complementary ab initio framework for nuclear weak decays and opens a pathway toward constraining 0νββ NMEs in heavier candidate nuclei using experimentally accessible 2νββ-decay data.