Reconstruction of f(T) Gravity with Interacting Variable-Generalised Chaplygin Gas and the Thermodynamics with Corrected Entropies
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Surajit Chattopadhyay
Abstract
This article reports a study on variable-generalised Chaplygin gas (VGCG) interacting with pressureless dark matter (DM) with interaction term Q chosen in the form Q=3HδρΛ, where ρΛ denotes the density of the VGCG. Detailed cosmology of the interacting VGCG has been studied and a quintom behaviour of the equation of state (EoS) parameter has been observed. A statefinder analysis has shown attainment of ΛCDM fixed point by the interacting VGCG. Subsequently, a reconstruction scheme for f(T) gravity has been presented based on the interacting VGCG with power-law form of scale factor. The EoS parameter corresponding to the reconstructed f(T) has shown quintom behaviour. Finally, we have studied the generalised second law (GSL) of thermodynamics in reconstructed f(T) cosmology considering the universe as a closed bounded system with future event horizon as the cosmological boundary. We have associated two different entropies with the cosmological horizons with a logarithmic correction term and a power-law correction term. We have studied the validity of the GSL for both of these corrections.
Acknowledgement
Financial support from Science and Engineering Research Board, DST, Govt of India under project grant no. SR/FTP/PS-167/2011 is thankfully acknowledged. Sincere thanks are due to the anonymous reviewers for their supportive comments and suggestions.
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Artikel in diesem Heft
- Frontmatter
- Hydrogen and Carbon Vapour Pressure Isotope Effects in Liquid Fluoroform Studied by Density Functional Theory
- Analytic Approximations to Nonlinear Boundary Value Problems Modeling Beam-Type Nano-Electromechanical Systems
- Resistance Distances and Kirchhoff Index in Generalised Join Graphs
- Residual Symmetries and Interaction Solutions for the Classical Korteweg-de Vries Equation
- Nanofluidic Transport over a Curved Surface with Viscous Dissipation and Convective Mass Flux
- Reconstruction of f(T) Gravity with Interacting Variable-Generalised Chaplygin Gas and the Thermodynamics with Corrected Entropies
- Peristaltic Flow of Rabinowitsch Fluid in a Curved Channel: Mathematical Analysis Revisited
- Analysis of the Laminar Newtonian Fluid Flow Through a Thin Fracture Modelled as a Fluid-Saturated Sparsely Packed Porous Medium
- Lie Symmetries and Conservation Laws of the Generalised Foam-Drainage Equation
- Lie Symmetry Analysis, Analytical Solutions, and Conservation Laws of the Generalised Whitham–Broer–Kaup–Like Equations
- Discrete and Semidiscrete Models for AKNS Equation
Artikel in diesem Heft
- Frontmatter
- Hydrogen and Carbon Vapour Pressure Isotope Effects in Liquid Fluoroform Studied by Density Functional Theory
- Analytic Approximations to Nonlinear Boundary Value Problems Modeling Beam-Type Nano-Electromechanical Systems
- Resistance Distances and Kirchhoff Index in Generalised Join Graphs
- Residual Symmetries and Interaction Solutions for the Classical Korteweg-de Vries Equation
- Nanofluidic Transport over a Curved Surface with Viscous Dissipation and Convective Mass Flux
- Reconstruction of f(T) Gravity with Interacting Variable-Generalised Chaplygin Gas and the Thermodynamics with Corrected Entropies
- Peristaltic Flow of Rabinowitsch Fluid in a Curved Channel: Mathematical Analysis Revisited
- Analysis of the Laminar Newtonian Fluid Flow Through a Thin Fracture Modelled as a Fluid-Saturated Sparsely Packed Porous Medium
- Lie Symmetries and Conservation Laws of the Generalised Foam-Drainage Equation
- Lie Symmetry Analysis, Analytical Solutions, and Conservation Laws of the Generalised Whitham–Broer–Kaup–Like Equations
- Discrete and Semidiscrete Models for AKNS Equation
