Abstract
The cross section for coherent elastic neutrino-nucleus scattering (CE$\nu$NS) depends on the response of the target nucleus to the external current, in the Standard Model (SM) mediated by the exchange of a $Z$ boson. This is typically subsumed into an object called the weak form factor of the nucleus. Here, we provide results for this form factor calculated using the large-scale nuclear shell model for a wide range of nuclei of relevance for current CE$\nu$NS experiments, including cesium, iodine, argon, fluorine, sodium, germanium, and xenon. In addition, we provide the responses needed to capture the axial-vector part of the cross section, which does not scale coherently with the number of neutrons, but may become relevant for the SM prediction of CE$\nu$NS on target nuclei with nonzero spin. We then generalize the formalism allowing for contributions beyond the SM. In particular, we stress that in this case, even for vector and axial-vector operators, the standard weak form factor does not apply anymore, but needs to be replaced by the appropriate combination of the underlying nuclear structure factors. We provide the corresponding expressions for vector, axial-vector, but also (pseudo-)scalar, tensor, and dipole effective operators, including two-body-current effects as predicted from chiral effective field theory. Finally, we update the spin-dependent structure factors for dark matter scattering off nuclei according to our improved treatment of the axial-vector responses.
Highlights
CEνNS, suggested as a probe of the weak current as early as 1974 [1], was observed by the COHERENT collaboration in 2017 [2]
We provide the corresponding expressions for vector, axial-vector, andscalar, tensor, and dipole effective operators, including two-body-current effects as predicted from chiral effective field theory (EFT)
In this paper we have provided a detailed account of the CEνNS cross section both within the Standard Model (SM) and beyond
Summary
CEνNS, suggested as a probe of the weak current as early as 1974 [1], was observed by the COHERENT collaboration in 2017 [2]. [37], but in addition the shell-model approach allows us to address the spin-dependent (SD) responses, which are similar, but somewhat different to the ones in SD dark matter searches To this end, we first derive the decomposition of the cross section into Wilson coefficients of effective operators, hadronic matrix elements, and nuclear structure factors. We demonstrate how the standard weak form factor emerges when combining all these ingredients into a single object This analysis shows that even for the coherent part of the nuclear response four different underlying structure factors contribute to the cross section. Effective Lagrangians As a first step, we review the operator basis for CEνNS [36,46]1
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