Torsion-Induced Modification to Friedmann Equations in AdSL4 Gauged Gravity

Abstract

We study the solution of the gravitational field equations in AdSL4-gauged gravity, a gauge-theoretic extension of general relativity based on the AdSL4 algebra. In this formulation, the antisymmetric gauge field Bab, associated with additional AdSL4 tensorial generators, induces space-time torsion via the relation Kab=μ Bab, where Kab denotes the contorsion 1-form. The presence of torsion modifies both the spin connection and curvature, leading to an extended set of Einstein-Cartan field equations. Focusing on spatially homogeneous and isotropic cosmological backgrounds, we derive the modified Friedmann equations which explicitly incorporate the torsional contribution. The resulting acceleration equation admits de Sitter-like solutions in which cosmic acceleration originates purely from the gauge-theoretic structure of enlarged four-dimensional space-time symmetries. Within this formulation, the dynamical components of the gauge field Bab emerge naturally as a source of the effective cosmological constants, without the introduction of exotic matter sources. Furthermore, our analysis shows that the torsion-driven cosmological phase in AdSL4-gauged gravity can reproduce an effective equation-of-state parameter ωB=-1/3, establishing a connection between space-time torsion and cosmic-string-like dynamics.

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