Measuring the Shape of Kerr Black Holes at the Photon Orbit

TL;DR

This paper explores how to measure the Lyapunov exponent of photon rings around Kerr black holes using black hole images, demonstrating that upcoming observations can achieve precise gravitational measurements despite astrophysical uncertainties.

Contribution

It proposes a method to measure the Lyapunov exponent from photon ring observations, accounting for astrophysical errors, and shows that high-precision gravitational data is attainable.

Findings

Potential to measure Lyapunov exponent to 10% accuracy from n=2 photon ring

Measurement of the Lyapunov exponent can reach 1% uncertainty at n=3 photon ring

Upcoming black hole imaging can indirectly determine gravitational properties

Abstract

The bright ring-like structures observed in the images of M87* and SgrA* captured by the Event Horizon Telescope strongly support the validity of general relativity. Lensed images of the emission region, often referred to as photon rings in this context, are a direct consequence of the unstable dynamics of null geodesics near the spherical photon orbit in the Kerr spacetime. The order of the lensed image can be characterized by the number of half-orbits the photons complete before reaching the observer, with higher-order photon rings produced by null geodesics that circle the black hole more times. However, low-order rings are significantly influenced by the astrophysical environment. Measuring the Lyapunov exponent requires probing the exponentially small differences between successive photon rings or between photon rings and the shadow. We investigate potential astrophysical sources of systematic error the estimation of Lyapunov exponent, including the location of the observed emission, and especially at low photon ring order. We show that it is nevertheless possible to measure this purely gravitational quantity to roughly 10% and 1% systematic uncertainty by resolving the n=2 and n=3 photon rings with the shadow size, respectively. Therefore, the forthcoming black hole imaging efforts to capture, even if indirectly, the n=2 photon ring can result in a measurement of the Lyapunov exponent that is not limited by astrophysical uncertainties.