This thesis investigates the concept of dark matter (DM) through a two-component model interacting with the Standard Model (SM) via Higgs and Z portals. It highlights the necessity of extending existing models to account for dark matter and neutrino masses in a coherent framework. The authors postulate that their model could provide insights into DM stability and offers several theoretical and experimental constraints. The findings build on prior work and aim to broaden the understanding of potential DM candidates in particle physics.
In recent years, a class of models has been proposed to incorporate the neutrino mass generation and the existence of DM in a unified framework.
Several simple extensions of the SM that can account for the DM have already been studied, providing a deeper understanding of dark matter candidates.
The results are based on the work: Arindam Das, Shivam Gola, Sanjoy Mondal, Nita Sinha, "Two-Components Scalar and Fermionic Dark Matter candidates in a generic U(1)𝑋 model, Phys.Lett.B 2022.137117."
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