Abstract

We generalize and unify the fleft( R,Tright) and fleft( R,L_mright) type gravity models by assuming that the gravitational Lagrangian is given by an arbitrary function of the Ricci scalar R, of the trace of the energy–momentum tensor T, and of the matter Lagrangian L_m, so that L_{grav}=fleft( R,L_m,Tright) . We obtain the gravitational field equations in the metric formalism, the equations of motion for test particles, and the energy and momentum balance equations, which follow from the covariant divergence of the energy–momentum tensor. Generally, the motion is non-geodesic, and takes place in the presence of an extra force orthogonal to the four-velocity. The Newtonian limit of the equations of motion is also investigated, and the expression of the extra acceleration is obtained for small velocities and weak gravitational fields. The generalized Poisson equation is also obtained in the Newtonian limit, and the Dolgov–Kawasaki instability is also investigated. The cosmological implications of the theory are investigated for a homogeneous, isotropic and flat Universe for two particular choices of the Lagrangian density fleft( R,L_m,Tright) of the gravitational field, with a multiplicative and additive algebraic structure in the matter couplings, respectively, and for two choices of the matter Lagrangian, by using both analytical and numerical methods.

Highlights

  • The simplest answer to explain the late time acceleration is to resort again to the old cosmological constant, which was introduced by Einstein to build the first general relativistic cosmological model [6]

  • We investigate the effects of the two possible different choices of the matter Lagrangian (Lm = p and Lm = −ρ, respectively) on the description of the cosmological evolution

  • Let us start with taking the covariant derivation of the gravitational field equations Eq (12)

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Summary

The divergence of the matter energy–momentum tensor

Let us start with taking the covariant derivation of the gravitational field equations Eq (12). One should note that in the case of perfect fluid and scalar field theory we have Aν = 0. Where we have defined fm = fT + 2 fL. Equation (21) is direct a consequence of the presence of the matter fields in the expression of the gravitational Lagrange density, given by the function f (R, Lm, T ). One can immediately see that in the case of fT = 0 = fL , the matter content of the Universe is conserved. By using the traceless representation of the field equations, one can obtain the non-conservation of the energy–

The energy and momentum balance equations
The variational principle for the equation of motion of a test particle
The Newtonian limit of the equation of motion
The modified Poisson equation
The Dolgov–Kawasaki instability
Generalized Friedmann equations
The radiation dominated Universe
The dust Universe
Numerical results
Numerical solutions
Discussions and final remarks

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