Perturbed $f(R)$ gravity coupled with neutrinos: exploring cosmological implications

Abstract: We conduct a thorough examination of cosmological parameters within the context of $f(R)$ gravity coupled with neutrinos, leveraging a diverse array of observational datasets, including Cosmic Microwave Background (CMB), Cosmic Chronometers (CC), Baryon Acoustic Oscillations (BAO), and Pantheon supernova data. Our analysis unveils compelling constraints on pivotal parameters such as the sum of neutrino masses ($\sum m_{\nu}$), the interaction strength parameter ($\Gamma$), sound speed ($c_s$), Jean's wavenumbers ($k_J$), redshift of non-relativistic matter ($z_{\rm nr}$), and the redshift of the Deceleration-Acceleration phase transition ($z_{\rm DA}$). The incorporation of neutrinos within the $f(R)$ gravity framework emerges as a key factor significantly influencing cosmic evolution, intricately shaping the formation of large-scale structures and the dynamics of cosmic expansion. Additionally, a detailed analysis of bulk flow direction and amplitude across various redshifts provides valuable insights into the nature of large-scale structures. A notable aspect of our model is the nuanced integration of $f(R)$ gravity theory with neutrinos, representing a distinctive approach to unraveling cosmological phenomena. This framework, unlike previous models, explicitly considers the impact of neutrinos on gravitational interactions, the formation of large-scale structures, and the overarching dynamics of cosmic expansion within the $f(R)$ gravity paradigm. Furthermore, our study addresses the Hubble tension problem by comparing $H_0$ measurements within our model, offering a potential avenue for reconciling discrepancies. Our findings not only align with existing research but also contribute novel perspectives to our understanding of dark energy, gravitational interactions, and the intricate challenges posed by the Hubble tension.