Add to ORKGWe present a neutrino mass model based on modular symmetry with the fewest input parameters to date, which successfully accounts for the 12 lepton masses and mixing parameters through 6 real free parameters including the modulus. The neutrino masses are predicted to be normal ordering, the atmospheric angle $\theta_{23}$ is quite close to maximal value and the Dirac CP phase $\delta_{CP}$ is about $1.34\pi$. We also study the soft supersymmetry breaking terms due to the modulus $F$-term in this minimal model, which are constrained to be the non-holomorphic modular forms. The radiative lepton flavor violation process $\mu\to e\gamma$ is discussed.Comment: 24 pages, 4 figure
In the framework of the modular symmetry approach to lepton flavour, we consider a class of theories...
Journal of High Energy Physics 2013.11 (2013): 187 reproduced by permission of Scuola Internazionale...
We study models of lepton masses and mixing based on broken modular invariance. We consider invarian...
We present a neutrino mass model based on modular symmetry with the fewest input parameters to date,...
We explore alternative descriptions of the charged lepton sector in modular invariant models of lep...
We investigate models of charged lepton and neutrino masses and lepton mixing based on broken modula...
We investigate models of charged lepton and neutrino masses and lepton mixing based on broken modula...
We analyze a large set of modular invariant models of lepton masses and mixing angles, pointing out ...
Neutrino flavor mixing is explained within the recently proposed low-scale minimal linear seesaw mod...
The problem of normalisation of the modular forms in modular invariant lepton and quark flavour mode...
We study a neutrino mass model with $A_4$ flavor symmetry using a type-I seesaw mechanism. The inclu...
We construct phenomenologically viable models of lepton masses and mixing based on modular A 4 invar...
We have performed a systematical study of the eclectic flavor group $\Delta(27)\rtimes S_3$ which is...
We investigate minimal phenomenologically viable models of charged lepton and neutrino masses and le...
Abstract We investigate models of charged lepton and neutrino masses and lepton mixing based on brok...
In the framework of the modular symmetry approach to lepton flavour, we consider a class of theories...
Journal of High Energy Physics 2013.11 (2013): 187 reproduced by permission of Scuola Internazionale...
We study models of lepton masses and mixing based on broken modular invariance. We consider invarian...
We present a neutrino mass model based on modular symmetry with the fewest input parameters to date,...
We explore alternative descriptions of the charged lepton sector in modular invariant models of lep...
We investigate models of charged lepton and neutrino masses and lepton mixing based on broken modula...
We investigate models of charged lepton and neutrino masses and lepton mixing based on broken modula...
We analyze a large set of modular invariant models of lepton masses and mixing angles, pointing out ...
Neutrino flavor mixing is explained within the recently proposed low-scale minimal linear seesaw mod...
The problem of normalisation of the modular forms in modular invariant lepton and quark flavour mode...
We study a neutrino mass model with $A_4$ flavor symmetry using a type-I seesaw mechanism. The inclu...
We construct phenomenologically viable models of lepton masses and mixing based on modular A 4 invar...
We have performed a systematical study of the eclectic flavor group $\Delta(27)\rtimes S_3$ which is...
We investigate minimal phenomenologically viable models of charged lepton and neutrino masses and le...
Abstract We investigate models of charged lepton and neutrino masses and lepton mixing based on brok...
In the framework of the modular symmetry approach to lepton flavour, we consider a class of theories...
Journal of High Energy Physics 2013.11 (2013): 187 reproduced by permission of Scuola Internazionale...
We study models of lepton masses and mixing based on broken modular invariance. We consider invarian...