Spherical Gravitational Collapse in 4D Einstein-Gauss-Bonnet theory

Abstract

In this paper, we study spherical gravitational collapse of inhomogeneous pressureless matter in a well-defined n →4d limit of the Einstein-Gauss-Bonnet gravity. The collapse leads to either a black hole or a massive naked singularity depending on time of formation of trapped surfaces. More precisely, horizon formation and its time development is controlled by relative strengths of the Gauss-Bonnet coupling (λ) and the Misner-Sharp mass function F(r,t) of collapsing sphere. We find that, if there is no trapped surfaces on the initial Cauchy hypersurface and F(r,t)< 2λ, the central singularity is massive and naked. When this inequality is equalised or reversed, the central singularity is always censored by spacelike/timelike spherical marginally trapped surface of topology S2× R, which eventually becomes null and coincides with the event horizon at equilibrium. These conclusions are verified for a wide class of mass profiles admitting different initial velocity conditions. Hence, our result implies that the 4d Einstein-Gauss-Bonnet generically violates the cosmic censorship conjuncture. Further implications of this violation from the perspective of visibility of causal signals from the spacetime singularity are also discussed.