Tsallis holographic inflation in f(R,T) gravity: CMB constraints, reheating, and swampland implications
Abstract
Understanding how early-universe inflation may emerge from generalized holographic energy densities within modified gravity motivates the present analysis. We develop a self-consistent inflationary scenario in which the Tsallis holographic dark energy (THDE) density effectively acts as the inflaton potential in f(R,T) gravity. Using the Granda-Oliveros infrared cutoff, we derive the corresponding slow-roll relations and identify a broad region of the parameter space (α,β,δ,λ) that remains consistent with ACT DR6 (P-ACT-LB) constraints. By exploiting the dependence of the THDE density on the Hubble rate, we reconstruct the inflaton potential V(ϕ) and show that both the field excursion Δϕ and the normalized potential gradient |V'|/(V Mp) are predominantly controlled by the matter-geometry coupling λ. We demonstrate that λ O(102) suppresses the field excursion below the Planck scale and ensures |V'|/(V Mp) 1, thereby satisfying both the distance conjecture and the refined de Sitter swampland bound. We also analyze the reheating stage. In addition to the primordial nucleosynthesis requirement T BBN ≈ 4~MeV, which sets a lower limit on the reheating temperature, the observational bound ΔN eff 0.17 imposes an additional constraint from primordial gravitational waves (PGWs). During stiff reheating phases with ω re > 1/3, the high-frequency PGW spectrum is significantly enhanced, producing a distinct signature that may fall within the sensitivity of upcoming detectors. Overall, this work provides an observationally consistent realization of holographic inflation in f(R,T) gravity, jointly constrained by CMB data, swampland criteria, reheating physics, and PGW limits.
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