Linking and causality in globally hyperbolic spacetimes
Abstract
The linking number lk is defined if link components are zero homologous. Our affine linking invariant alk generalizes lk to the case of linked submanifolds with arbitrary homology classes. We apply alk to the study of causality in Lorentz manifolds. Let Mm be a spacelike Cauchy surface in a globally hyperbolic spacetime (Xm+1, g). The spherical cotangent bundle ST*M is identified with the space N of all null geodesics in (X,g). Hence the set of null geodesics passing through a point x∈ X gives an embedded (m-1)-sphere Sx in N=ST*M called the sky of x. Low observed that if the link (Sx, Sy) is nontrivial, then x,y∈ X are causally related. This motivated the problem (communicated by Penrose) on the Arnold's 1998 problem list to apply link theory to the study of causality. The spheres Sx are isotopic to fibers of (ST*M)2m-1 Mm. They are nonzero homologous and lk(Sx,Sy) is undefined when M is closed, while alk(Sx, Sy) is well defined. Moreover, alk(Sx, Sy)∈ Z if M is not an odd-dimensional rational homology sphere. We give a formula for the increment of under passages through Arnold dangerous tangencies. If (X,g) is such that alk takes values in and g is conformal to g' having all the timelike sectional curvatures nonnegative, then x, y∈ X are causally related if and only if alk(Sx,Sy)≠ 0. We show that x,y in nonrefocussing (X, g) are causally unrelated iff (Sx, Sy) can be deformed to a pair of Sm-1-fibers of ST*M M by an isotopy through skies. Low showed that if (, g) is refocussing, then M is compact. We show that the universal cover of M is also compact.
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