Black Hole Production in Particle Collisions and Higher Curvature Gravity

Abstract

We revisit the problem of black hole production in transplanckian particle collisions, in the context of large extra dimensions scenarios of TeV-scale gravity. We question the validity of the standard description of this process (two colliding Aichelburg-Sexl shock waves in classical Einstein gravity). We observe that the classical spacetime has large curvature along the transverse collision plane, as signaled by the blowing up curvature invariant (R_ijkl)^2. Thus quantum gravity effects, and in particular higher curvature corrections to the Einstein gravity, cannot be ignored. To give a specific example of what may happen, we re-analyze the collision in the Einstein-Lanczos-Lovelock gravity theory, which modifies the Einstein-Hilbert Lagrangian by adding a particular `Gauss-Bonnet' combination of curvature squared terms. The analysis uses a series of approximations, which reduce the field equations to a tractable second order nonlinear PDE of the Monge-Ampere type. We find that the resulting spacetime is significantly different from the pure Einstein case everywhere to the future of the transverse collision plane. Our considerations cast serious doubts on the geometric cross section estimate, which is based on the classical Einstein gravity description of the black hole production process.