THE LOCAL AND GLOBAL GEOMETRICAL ASPECTS OF THE TWIN PARADOX IN STATIC SPACETIMES: I. THREE SPHERICALLY SYMMETRIC SPACETIMES

We investigate local and global properties of timelike geodesics in three static, spherically symmetric spacetimes. These properties are of its own mathematical relevance and provide a solution of the physical 'twin paradox' problem. The latter means that we focus our studies on the search of the longest timelike geodesics between two given points. Due to problems with solving the geodesic deviation equation, we restrict our investigations to radial and circular (if exist) geodesics. On these curves we find general Jacobi vector fields, determine by means of them sequences of conjugate points and with the aid of the comoving coordinate system and the spherical symmetry we determine the cut points. These notions identify segments of radial and circular geodesics which are locally or globally of maximal length. In de Sitter spacetime all geodesics are globally maximal. In CAdS and Bertotti-Robinson spacetimes, the radial geodesics which infinitely many times oscillate between antipodal points in the space contain infinite number of equally separated conjugate points and there are no other cut points. Yet in these two spacetimes each outgoing or ingoing radial geodesic which does not cross the centre is globally of maximal length. Circular geodesics exist only in CAdS spacetime and contain an infinite sequence of equally separated conjugate points. The geodesic curves which intersect the circular ones at these points may either belong to the two-surface theta = pi/2 or lie outside it.