Abstract
In this letter, we use a recent wormhole metric known as a ringhole [Gonzalez-Diaz, Phys. Rev. D 54, 6122, 1996] to determine the surface topology and the deflection angle of light in the weak limit approximation using the Gauss-Bonnet theorem (GBT). We apply the GBT and show that the surface topology at the wormhole throat is indeed a torus by computing the Euler characteristic number. As a special case of the ringhole solution, one can find the Ellis wormhole which has the surface topology of a 2-sphere at the wormhole throat. The most interesting results of this paper concerns the problem of gravitational deflection of light in the spacetime of a ringhole geometry by applying the GBT to the optical ringhole geometry. It is shown that, the deflection angle of light depends entirely on the geometric structure of the ringhole geometry encoded by the parameters b0 and a, being the ringhole throat radius and the radius of the circumference generated by the circular axis of the torus, respectively. As special cases of our general result, the deflection angle by Ellis wormhole is obtained. Finally, we work out the problem of deflection of relativistic massive particles and show that the deflection angle remains unaltered by the speed of the particles.
Highlights
Solving the Einstein’s field equations of general relativity leads to very interesting solutions which can be interpreted as tunnel-like structures connecting two different spacetime regions, known as wormholes
We have studied the surface topology and the deflection angle of light in the ringhole spacetime using Gauss-Bonnet theorem (GBT)
We have shown that the surface topology of the ringhole at the throat is a torus with the Euler characteristic number χtorus = 0
Summary
Solving the Einstein’s field equations of general relativity leads to very interesting solutions which can be interpreted as tunnel-like structures connecting two different spacetime regions, known as wormholes. Einstein and Rosen [2] introduced a coordinate transformation which eliminates the curvature singularity, this lead to the famous bridge-like structure connecting two spacetime regions known as Einstein-Rosen bridges They tried to interpret these solutions as a model for elementary particles, but that idea turned out to be unsuccessful. Crisnejo and Gallo used the GBT to study the deflection angle of massive particles by static spacetimes [40,41], while Jusufi investigated the gravitational deflection of massive particles by stationary spacetimes [42] This method has been applied in the context of static/rotating wormholes and topological defects [43,44,45,46,47,48,49,50,51,52], including the recent work by Ono et al [53].
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