TL;DR
This paper develops a method to determine deformations of black hole geometries from observational data, linking these deformations to physical fields and Einstein equations, with applications to the Hayward space-time.
Contribution
It introduces a way to reconstruct effective black hole metrics from telemetric data and connects metric deformations to physical fields via invariant eigenvalues.
Findings
Series expansion coefficients are uniquely determined from outside measurements.
Constructed an effective Einstein equation for deformed black holes.
Applied framework to the Hayward space-time example.
Abstract
In recent works, a framework has been developed to describe (quantum) deformed, spherically symmetric and static black holes in four dimensions. The key idea of this so-called Effective Metric Description (EMD) is to parametrise deformations of the classical Schwarzschild geometry by two functions that depend on a physical quantity and which are calculated in a self-consistent way as series expansions in the vicinity of the horizon. In this work we further strengthen this framework by first demonstrating that the corresponding series expansion coefficients can be completely and uniquely determined from measurements that are accessible for observers outside of the event horizon: we propose a Gedankenexperiment, consisting of probes following a free-falling trajectory that send signals to a stationary observer and show how an EMD can be constructed from suitable telemetric data.…
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