Deflection angle in the strong deflection limit: A perspective from local geometrical invariants and matter distributions

Abstract

In static, spherically symmetric spacetimes, the deflection angle of photons in the strong deflection limit exhibits a logarithmic divergence. We introduce an analytical framework that clarifies the physical origin of this divergence by employing local, coordinate-invariant geometric quantities alongside the properties of the matter distribution. In contrast to conventional formulations -- where the divergence rate a is expressed via coordinate-dependent metric functions -- our approach relates a to the components of the Einstein tensor in an orthonormal basis adapted to the spacetime symmetry. By applying the Einstein equations, we derive the expression align* a=11-8π Rm2(m+m), align* where m and m denote the local energy density and tangential pressure evaluated at the photon sphere of areal radius Rm. This result reveals that a is intrinsically governed by the local matter distribution, with the universal value a=1 emerging when m+m=0. Notably, this finding resolves the long-standing puzzle of obtaining a=1 in a class of spacetimes supported by a massless scalar field. Furthermore, these local properties are reflected in the frequencies of quasinormal modes, suggesting a profound connection between strong gravitational lensing and the dynamical response of gravitational wave signals.

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