Tripathy, S. K., Pal, S., & Mishra, B. (2024). Non-minimally coupled teleparallel scalar field reconstruction of matter bounce scenario. arXiv preprint, arXiv:2410.23307v1.
This study aims to reconstruct the scalar field potential required for an extended matter bounce scenario within the framework of f(T, ϕ) gravity and investigate its cosmological implications.
The authors employ the field equations of f(T, ϕ) gravity in a homogeneous and isotropic FLRW spacetime. They integrate the Klein-Gordon equation to reconstruct the scalar field potential for an extended matter bounce scenario, assuming a specific power-law dependence of the scalar field on the scale factor. The cosmological implications of the reconstructed potential are then studied for two different functional forms of G(T), representing specific models within f(T, ϕ) gravity.
The research demonstrates the feasibility of realizing an extended matter bounce scenario within the framework of f(T, ϕ) gravity. The reconstructed scalar field potential and the resulting cosmological evolution are influenced by the choice of model parameters and the specific form of the non-minimal coupling function.
This study contributes to the ongoing research on alternative gravity theories and their potential to address cosmological puzzles like the Big Bang singularity. The findings provide insights into the dynamics of the early universe and the role of scalar fields in driving cosmic evolution.
The study primarily focuses on two specific functional forms of G(T). Exploring other viable forms and their cosmological implications could provide a more comprehensive understanding. Further investigation into the observational constraints on the model parameters and comparing the predictions with observational data would be crucial for validating the proposed scenario.
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