Your search keyword '"Sahu, Purushottam"' showing total 4 results

1. Leptogenesis in a Left-Right Symmetric Model with double seesaw.

Author

Patel, Utkarsh, Adarsh, Pratik, Patra, Sudhanwa, and Sahu, Purushottam

Subjects

STERILE neutrinos, NEUTRINO mass, BOLTZMANN'S equation, CURRENT fluctuations, NEUTRINOS, LEPTON number, NEUTRINOLESS double beta decay

Abstract

We explore the connection between low-scale CP-violating Dirac phase (δ) and high-scale leptogenesis in a Left-Right Symmetric Model (LRSM) with scalar bidoublet and doublets. The fermion sector of the model is extended with one sterile neutrino (SL) per generation to implement a double seesaw mechanism in the neutral fermion mass matrix. The double seesaw is performed via the implementation of type-I seesaw twice. The first seesaw facilitates the generation of Majorana mass term for heavy right-handed (RH) neutrinos (NR), and the light neutrino mass becomes linearly dependent on SL mass in the second. In our framework, we have taken charge conjugation (C) as the discrete left-right (LR) symmetry. This choice assists in deriving the Dirac neutrino mass matrix (MD) in terms of the light and heavy RH neutrino masses and light neutrino mixing matrix UPMNS (containing δ). We illustrate the viability of unflavored thermal leptogenesis via the decay of RH neutrinos by using the obtained MD with the masses of RH neutrinos as input parameters. A complete analysis of the Boltzmann equations describing the asymmetry evolution is performed in the unflavored regime, and it is shown that with or without Majorana phases, the CP-violating Dirac phase is sufficient to produce the required asymmetry in the leptonic sector within this framework for a given choice of input parameters. Finally, we comment on the possibility of constraining our model with the current and near-future oscillation experiments, which are aimed at refining the value of δ. [ABSTRACT FROM AUTHOR]

Published

2024

2. Gauge coupling unification in a minimal non-supersymmetric E6 GUT.

Author

Dash, Chandini, Mishra, Snigdha, Patra, Sudhanwa, and Sahu, Purushottam

Subjects

PROTON decay, Z bosons, FERMIONS, MAGNETIC moments, MUONS, NEUTRINOS, GAUGE bosons

Abstract

We consider a minimal renormalizable non-supersymmetric E 6 Grand Unified Theory using fundamental representation 27 for fermions and scalars. The scalar with adjoint representation 78 is also taken for direct breaking of E 6 to SM. The proposed model, guided by TeV-scale vector-like fermions and scalar leptoquark, offers successful gauge unification even in the absence of any intermediate symmetry. Embedded with threshold corrections, it is shown to be compatible with the present experimental limit on proton decay lifetime. The unique feature of the model shows that the GUT threshold corrections to the unification mass is controlled by superheavy gauge bosons only, thereby minimizing the uncertainty of the GUT predictions. The scalar leptoquark and vector-like fermions residing in 27 representation can explain flavor physics anomalies like R D (∗) as reported by the LHCb collaboration and the muon anomalous magnetic moment reported by the recent muon g − 2 experiment at Fermilab. The model can also predict a sub-eV scale neutrino at one-loop level via exchange of W and Z gauge bosons through MRIS mechanism. [ABSTRACT FROM AUTHOR]

Published

2024

3. Neutrino mass and lepton flavor violation in A4-based left–right symmetric model with linear seesaw.

Author

Sahu, Purushottam, Patra, Sudhanwa, and Pritimita, Prativa

Subjects

*NEUTRINO mass, *GAUGE symmetries, *NEUTRINOS, *NEUTRINO oscillation

Abstract

We explore an A 4 flavor-based left–right symmetric model where neutrino masses and mixing are explained through linear seesaw mechanism. Taking A 4 flavor symmetry and left–right gauge symmetry together and adding a low-scale seesaw mechanism gives the advantage of (a) getting diagonal structures for both charged lepton mass matrix and Dirac neutrino mass matrix, (b) simpler relations among neutrino observables in the model and (c) large light-heavy neutrino mixing which gives dominant contributions to various lepton flavor violating decays like μ → e γ , μ → e e e , μ → e. By saturating the experimental bounds on these decays we derive constraints on input model parameters and study analytically as well as numerically the correlation among model parameters and their dependence on experimentally determined neutrino parameters like 1 2 , 2 3 , 1 3 , Δ m atm 2 , Δ m sol 2 . We also study CP-violation via Jarlskog invariants and show extra contributions to CP-violating effects that the model generates due to unitarity violation in the neutrino sector. [ABSTRACT FROM AUTHOR]

Published

2022

4. LHC signatures of sterile neutrinos in a minimal radiative extended seesaw framework.

Author

Patra, Sudhanwa, Patel, Utkarsh, and Sahu, Purushottam

Subjects

STERILE neutrinos, NEUTRINOS, NEUTRINO mass, STANDARD model (Nuclear physics), BOSONS

Abstract

The presence of small neutrino masses and flavour mixings can be accounted for naturally in various models about extensions of the standard model, particularly in the seesaw mechanism models. In this work, we present a minimally extended seesaw framework with two right-handed neutrinos, where the active neutrino masses are derived in the radiative regime. Using the framework it can be shown that within certain mass limits, the light neutrino mass term can approach a form that is similar to its form under type-I seesaw mechanism. Apart from this, we show that the decay width of right-handed neutrinos (produced through the decay of W boson in a particle collider) is short enough to cause a sufficiently long lifetime for the particles, thus ensuring an observable displacement in the LHC between the production and decay vertices. We comment on the fact that these displaced vertex signatures thus can serve as a means to verify the existence of these right-handed neutrinos in future experiments. Lastly, we line up the possibility of our future work where the vertex signatures of particles greater than the mass of W boson can be worked upon. [ABSTRACT FROM AUTHOR]

Published

2022