Gravitational Foundations and Exact Solutions in n-Dimensional Fractional Cosmology

Three theoretically plausible techniques to developing a fractional scalar field cosmological model are pointed in this paper; the time-dependent kernel weighted action being then selected. Upon this choice, we proceed to establish (i) a time weighted action associated with the generalized scalar field cosmology; and (ii) a fractional cosmological model in $n$ dimensions considering the FLRW metric and a generalized version of the S\'{a}ez-Ballester (SB) theory. Our study focuses on the following purposes. Firstly, to investigate the fundamental gravitational structural features of the model, we analyze the dynamical behavior of the field equations, the fulfillment of the Bianchi identities, the associated conservation laws, and the application of the second Noether theorem at the background and first-order perturbation levels. Moreover, the model's distinguishing characteristics and theoretical differences from the corresponding standard scenarios are also investigated. Secondly, we aim to obtain exact analytical solutions and analyze the time evolution of key cosmological quantities, considering the fractional parameter effects. Furthermore, the model's predictions are compared with those of the corresponding standard models. Lastly, we propose new ideas to further generalize our model, with a focus on constructing an effective potential and investigating the conditions under which bounce solutions may emerge.