Two-body currents at finite momentum transfer and applications to M1 transitions
Abstract
We explore the impact of two-body currents (2BCs) at finite momentum transfer with a focus on magnetic dipole properties in 48Ca and 48Ti. To this end, we derive a multipole decomposition of 2BCs to fully include the momentum-transfer dependence in ab\,initio calculations. As application, we investigate the effects of 2BCs on the strong M1 transition at 10.23\,MeV in 48Ca using the valence-space in-medium similarity renormalization group (VS-IMSRG) with a set of non-implausible interactions as well as the 1.8/2.0 (EM) interaction. Experiments, such as (e,e') and (γ,n), disagree on the magnetic dipole strength B(M1) for this transition. Our VS-IMSRG results favor larger B(M1) values similar to recent coupled-cluster calculations. However, for this transition there are larger cancellations between the leading pion-in-flight and seagull 2BCs, so that future calculations including higher-order 2BCs are important. For validation of our results, we investigate additional observables in 48Ca as well as M1 transitions in 48Ti. For these, our results agree with experiment. Finally, our results show that for medium-mass nuclei 2BC contributions to M1 and Gamow-Teller transitions are, as expected, very different. Therefore, using similar quenching factors for both in phenomenological calculations is not supported from first principles.
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