SUSY breaking constraints on modular flavor S3 invariant SU(5) GUT model

In modular-invariant models of flavour, hierarchical fermion mass matrices may arise solely due to the proximity of the modulus τ to a point of residual symmetry. This mechanism does not require flavon fields, and modular weights are not analogous to Froggatt-Nielsen charges. Instead, we show that hierarchies depend on the decomposition of field representations under the residual symmetry group. We systematically go through the possible fermion field representation choices which may yield hierarchical structures in the vicinity of symmetric points, for the four smallest finite modular groups, isomorphic to S3, A4, S4, and A5, as well as for their double covers. We find a restricted set of pairs of representations for which the discussed mechanism may produce viable fermion (charged-lepton and quark) mass hierarchies. We present two lepton flavour models in which the charged-lepton mass hierarchies are naturally obtained, while lepton mixing is somewhat fine-tuned. After formulating the conditions for obtaining a viable lepton mixing matrix in the symmetric limit, we construct a model in which both the charged-lepton and neutrino sectors are free from fine-tuning.

Section: Jhep04(2021)206mentioning

confidence: 99%

Fermion mass hierarchies, large lepton mixing and residual modular symmetries

Novichkov

Penedo

Petcov

2021

“…Indeed, modular symmetry in the context of SU(5) GUTs was first studied in an (Γ 3 A 4 ) × SU(5) model in [14]. Other modular GUT models were subsequently constructed based on (Γ 2 S 3 ) × SU(5) [10,63], and (Γ 4 S 4 ) × SU(5) [64].…”

Section: Jhep04(2021)239mentioning

confidence: 99%

SU(5) GUTs with A4 modular symmetry

Chen

Ding

King

2021

We combine SU(5) Grand Unified Theories (GUTs) with A4 modular symmetry and present a comprehensive analysis of the resulting quark and lepton mass matrices for all the simplest cases. Classifying the models according to the representation assignments of the matter fields under A4, we find that there are seven types of SU(5) models with A4 modular symmetry. We present 53 benchmark models with the fewest free parameters. The parameter space of each model is scanned to optimize the agreement between predictions and experimental data, and predictions for the masses and mixing parameters of quarks and leptons are given at the best fitting points. The best fit predictions for the leptonic CP violating Dirac phase, the lightest neutrino mass and the neutrinoless double beta decay parameter when displayed graphically are observed to cover a wide range of possible values, but are clustered around particular regions, allowing future neutrino experiments to discriminate between the different types of models.

“…It was pointed out that the role of the FN flavon may be played by a singlet under both the gauge symmetry and the finite modular symmetry which carries a non-zero modular weight, called the weighton [65], leading to natural quark and lepton mass hierarchies. 2 The question of quark and lepton mass and mixing is necessarily simultaneously addressed in GUTs, and various SU(5) models have been proposed [45,49,[87][88][89] which include finite modular symmetries which act as family symmetries. Modular symmetry in the context of SU(5) GUTs was first studied in an (Γ 3 A 4 ) × SU(5) model in [49], then (Γ 2 S 3 ) × SU(5) [45,87], and (Γ 4 S 4 ) × SU(5) [88].…”

Section: Jhep04(2021)291mentioning

confidence: 99%

Twin modular S4 with SU(5) GUT

King

Zhou

2021

We discuss the SU(5) grand unified extension of flavour models with multiple modular symmetries. The proposed model involves two modular S4 groups, one acting in the charged fermion sector, associated with a modulus field value τT with residual $$ {Z}_3^T $$ Z 3 T symmetry, and one acting in the right-handed neutrino sector, associated with another modulus field value τSU with residual $$ {Z}_2^{SU} $$ Z 2 SU symmetry. Quark and lepton mass hierarchies are naturally generated with the help of weightons, which are SM singlet fields, where their non-zero modular weights play the role of Froggatt-Nielsen charges. The model predicts TM1 lepton mixing, and neutrinoless double beta decay at rates close to the sensitivity of current and future experiments, for both normal and inverted orderings, with suppressed corrections from charged lepton mixing due to the triangular form of its Yukawa matrix.