Abstract
Building UV completions of lepton-number-violating effective operators has proved to be a useful way of studying and classifying models of Majorana neutrino mass. In this paper we describe and implement an algorithm that systematises this model-building procedure. We use the algorithm to generate computational representations of all of the tree-level completions of the operators up to and including mass-dimension 11. Almost all of these correspond to models of radiative neutrino mass. Our work includes operators involving derivatives, updated estimates for the bounds on the new-physics scale associated with each operator, an analysis of various features of the models, and a look at some examples. We find that a number of operators do not admit any completions not also generating lower-dimensional operators or larger contributions to the neutrino mass, ruling them out as playing a dominant role in the neutrino-mass generation. Additionally, we show that there are at most five models containing three or fewer exotic multiplets that predict new physics that must lie below 100 TeV. Accompanying this work we also make available a searchable database containing all of our results and the code used to find the completions. We emphasise that our methods extend beyond the study of neutrino-mass models, and may be useful for generating completions of high-dimensional operators in other effective field theories. Example code: ref. [37].
Highlights
Superpositions of mass eigenstates and the probability of detecting a neutrino of a given flavour oscillates with distance
Oscillation experiments have shown that the mixing in the lepton sector is of a different structure and extent to that seen in quarks; and measurements from cosmology, neutrinoless double-beta decay and tritium beta decay strongly constrain the absolute scale of the neutrino masses
We show the new-physics scales Λ associated with neutrino-mass generation from the ∆L = 2 operators in the SM effective field theory (SMEFT) up to dimension 13, assuming unit operator coefficients and the dominance of third-generation couplings
Summary
We establish the conventions we employ throughout the rest of the paper: the nomenclature of fields and indices, our operational semantics and the classification of the lepton-number-violating operators on which our analysis is based. We highlight that this classification differs mildly from that found in earlier work, since our list includes additional structures as well as operators containing derivatives. We find the operators containing field-strength tensors to be uninteresting from the perspective of model building — a point justified in detail in section 3.2.1 — and choose not to include them in our classification
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