Exact Solutions of the Field Equations for Empty Space in the Nash Gravitational Theory
Journal article, Peer reviewed
Published version
Permanent lenke
http://hdl.handle.net/11250/2485376Utgivelsesdato
2017-02Metadata
Vis full innførselSamlinger
Originalversjon
Aadne, M. T., Grøn, Ø. (2017) Exact Solutions of the Field Equations for Empty Space in the Nash Gravitational Theory. Universe. 3(1). 10.3390/universe3010010Sammendrag
John Nash has proposed a new theory of gravity. We define a Nash-tensor equal to the curvature tensor appearing in the Nash field equations for empty space, and calculate its components for two cases: 1. A static, spherically symmetric space; and 2. The expanding, homogeneous and isotropic space of the Friedmann-Lemaitre-Robertson-Walker (FLRW) universe models. We find the general, exact solution of Nash’s field equations for empty space in the static case. The line element turns out to represent the Schwarzschild-de Sitter spacetime. Also we find the simplest non-trivial solution of the field equations in the cosmological case, which gives the scale factor corresponding to the de Sitter spacetime. Hence empty space in the Nash theory corresponds to a space with Lorentz Invariant Vacuum Energy (LIVE) in the Einstein theory. This suggests that dark energy may be superfluous according to the Nash theory. We also consider a radiation filled universe model in an effort to find out how energy and matter may be incorporated into the Nash theory. A tentative interpretation of the Nash theory as a unified theory of gravity and electromagnetism leads to a very simple form of the field equations in the presence of matter. It should be noted, however, that the Nash theory is still unfinished. A satisfying way of including energy momentum into the theory has yet to be found.