Cosmology of fractional gravity
Iván Salvador-García, Gianluca Calcagni
TLDR
A first study of classical fractional gravity cosmology derives Friedmann equations, revealing stable de Sitter and phantom/ghost-sustained bouncing solutions.
Key contributions
- Derived classical covariant nonlocal equations of motion for fractional gravity, reducing them to Friedmann equations.
- Found de Sitter is an exact stable cosmological solution within this framework.
- Identified bouncing exact solutions sustained by phantom or ghost fluids, with a new finite-future singularity.
- Confirmed a universality class of form factors, as different representations yield identical solutions.
Why it matters
This paper is the first to explore the cosmology of classical fractional gravity, a promising nonlocal candidate for a UV-complete quantum gravity theory. It offers fundamental insights into the cosmological implications, revealing stable de Sitter and exotic bouncing solutions, thus advancing our understanding of early universe models.
Original Abstract
This is a first study of the cosmology of classical fractional gravity, a nonlocal proposal endowed with self-adjoint fractional d'Alembertian operators which serves as the basis for an ultraviolet-complete theory of quantum gravity. We derive the classical covariant nonlocal equations of motion for an arbitrary fractional exponent $γ$ and reduce them to the Friedmann equations on a homogeneous and isotropic cosmological background. We find that de Sitter is an exact stable solution and that bouncing exact solutions are sustained by phantom ($w<-1$) or ghost ($ρ<0$) fluids, in the latter case with a new type of finite-future singularity in the barotropic index. Different representations of the form factor give exactly the same solutions, thus confirming that the formulation of fractional field theories relies on a universality class of form factors. We compare these preliminary results with what obtained in multi-fractional cosmological models mimicking the spacetime geometry of fractional quantum gravity.
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