Role of gravitational decoupling on theoretical insights of relativistic massive compact stars in the mass gap

Advancements in theoretical simulations of mass gap objects, particularly those resulting from neutron star mergers and massive pulsars, play a crucial role in addressing the challenges of measuring neutron star radii. In the light of this, we have conducted a comprehensive investigation of compact objects, revealing that while the distribution of black hole masses varies based on formation mechanisms, they frequently cluster around specific values. For instance, the masses observed in GW190814 (23.2+1.1-1.0M⊙) and GW200210 (24.1+7.5-4.6M⊙) exemplify this clustering. We employed the gravitational decoupling approach within the framework of standard general relativity and thus focusing on the strange star model. This model highlights the effects of deformation adjusted by the decoupling constant and the bag function. By analyzing the mass-radius limits of mass gap objects from neutron star mergers and massive pulsars, we can effectively constrain the free parameters in our model, allowing us to predict the radii and moments of inertia for these objects. The mass-radius (M - R) and mass-inertia (M - I) profiles demonstrate the robustness of our models. It is shown that as the decoupling constant β increases from 0 to 0.1 and the bag constant ℬg decreases from 70 MeV/fm3 to 55 MeV/fm3, the maximum mass reaches Mmax = 2.87 M⊙ with a radius of 11.20 km. In contrast, for β = 0, the maximum mass is Mmax = 2.48 M⊙ with a radius of 10.69 km. Similarly, it has been exhibited that as β decreases to 0, the maximum mass peaks at Mmax = 2.95 M⊙ for ℬg = 55 MeV/fm3 with a radius of 11.32 km. These results not only exceed the observed masses of compact stars but also correlate with recent findings from gravitational wave events like GW190814 and GW200210, underscoring the relevance of our models in exploring compact objects in the universe.