Cosmological structure growth in energy-momentum squared gravity

Abstract

We investigate the cosmological evolution of matter perturbations in the modified gravity model f(R,T2), where T2=TμνTμν denotes the quadratic contraction of the energy--momentum tensor. Using the gauge-invariant 1+3 covariant formalism, we study the evolution of the matter density contrast and analyze several growth observables, including the growth factor, the growth index, and the weighted growth rate fσ8. We consider representative values n=1/2 and n=1/4, which probe different regimes of the matter--geometry coupling. We show that the growth index decreases with increasing redshift and approaches the standard matter-dominated behavior at early times, while mild scale-dependent deviations from the ΛCDM model emerge at late times. The model predicts small departures from General Relativity for n=1/4, whereas stronger deviations appear for n=1/2 and larger values of the coupling parameter α. We further compare the theoretical predictions for fσ8 with current observational data and find that viable parameter choices remain within the observational 2σ bounds. These results indicate that f(R,T2) gravity can provide a viable description of late-time cosmic acceleration and large-scale structure formation while remaining consistent with current growth observations.