Covariant interpretation of proper infall times in Kerr spacetime

TL;DR

This paper studies proper infall times in Kerr and Schwarzschild black holes using a covariant approach, revealing how black hole rotation affects geodesic focusing and infall durations.

Contribution

It provides a covariant analysis of proper infall times in Kerr spacetime, highlighting the influence of black hole spin on geodesic focusing and congruence evolution.

Findings

Kerr spin parameter can lengthen or shorten infall times compared to Schwarzschild.

Differences in infall times are linked to Raychaudhuri equation components.

Rotation affects expansion and shear, altering geodesic focusing behaviors.

Abstract

We investigate proper infall times in the Schwarzschild and Kerr spacetimes from a covariant perspective, focusing on the role of black--hole rotation in the focusing properties of timelike geodesic congruences.To perform a geometrically consistent comparison between rotating and non--rotating black holes, we analyse infall trajectories between surfaces of equal circumferential radius in the equatorial plane. Using equatorial timelike geodesics in the test--particle limit, we compute and compare the corresponding proper infall times for different values of the specific energy $E$, specific angular momentum $L$, and black--hole spin parameter $a$. Within the equal circumferential-radius prescription adopted here, we show that Kerr angular momentum $a$ can produce longer or shorter integrated proper infall times relative to the Schwarzschild case, depending on the orbital configuration and energy regime considered. We then interpret these results within the covariant $1+3$ formalism of general relativity, in terms of the expansion, shear, and Raychaudhuri evolution of timelike congruences. Our analysis shows that the Kerr--Schwarzschild differences in proper infall times are encoded in the corresponding Raychaudhuri time integrand, which reflects a competition between the radial evolution of the expansion and the nonlinear focusing contribution driven by expansion and shear. Black--hole rotation modifies both effects in a systematic way, leading to distinct behaviours for prograde and retrograde infall configurations.