Cosmological Scenarios in f(Q,C) gravity with a dynamical degree of freedom

Abstract

The f(Q,C) theory, which extends symmetric teleparallel gravity by including the boundary term C in addition to the non-metricity scalar Q, provides a unifying framework that encompasses both f(Q) and f(R) gravities. In this work, we develop a comprehensive dynamical system analysis of f(Q,C) cosmology formulated within the non-coincident affine connection branches. Unlike the coincident case, these branches introduce a dynamical degree of freedom that significantly enriches the cosmological phase space. We show that even for simple power-law forms of the Lagrangian, the theory accommodates a broad spectrum of cosmic scenarios, including successive pressureless matter eras, stiff-matter phases between early inflation and dark matter domination, and late-time acceleration. Our analysis demonstrates that the Universe can naturally evolve from an initial de Sitter phase to a matter-dominated epoch and subsequently to a final de Sitter attractor, consistent with the observed thermal history. These results highlight the role of the dynamical connection in shaping cosmic evolution and underline the potential of f(Q,C) gravity as a viable alternative framework for addressing outstanding issues in modern cosmology.