Ab initio calculations of overlap integrals for $μ\to e$ conversion in nuclei

Abstract: In an effective-field-theory approach, the rate for $\mu\to e$ conversion in nuclei depends on a set of effective operators mediating the lepton-flavor-violating interaction at a high scale, renormalization group corrections that describe the evolution to lower scales, and hadronic and nuclear matrix elements that turn quark-level interactions into hadronic ones and then embed the latter into nuclear responses. In particular, combining information from $\mu\to e\gamma$, $\mu\to 3e$, and $\mu\to e $ conversion in nuclei, it becomes possible to disentangle different underlying sources of lepton flavor violation. However, to assess the discriminatory power it is critical that uncertainties at each step of the analysis be controlled and fully quantified. In this regard, nuclear response functions related to the coupling to neutrons are notoriously problematic, since they are not directly constrained by experiment. We address these shortcomings by combining ab initio calculations with a recently improved determination of charge distributions from electron scattering by exploiting strong correlations among charge, point-proton, and point-neutron radii and densities. We present overlap integrals for $^{27}$Al, $^{48}$Ca, and $^{48}$Ti including full covariance matrices, allowing, for the first time, for a comprehensive consideration of nuclear structure uncertainties in the interpretation of $\mu\to e$ experiments.