A Methodological Framework for Solving Einsteins Equations in Axially Symmetric Spacetimes

TL;DR

This paper introduces a new systematic method using the 1+3 tetrad formalism to derive axially symmetric solutions to Einstein's equations, reproducing known metrics and extending to hyperbolic geometries.

Contribution

It presents a novel approach that reformulates Einstein's equations into scalar first order equations, enabling the derivation of new solutions and extending existing models to hyperbolic configurations.

Findings

Reproduces Schwarzschild and Kerr solutions

Derives solutions in polar and hyperbolic geometries

Highlights role of Killing tensors in separability

Abstract

This work presents a novel methodology for deriving stationary and axially symmetric solutions to Einstein field equations using the 1+3 tetrad formalism. This approach reformulates the Einstein equations into first order scalar equations, enabling systematic resolution in vacuum scenarios. We derive two distinct solutions in polar and hyperbolic geometries by assuming the separability of a key metric function. Our method reproduces well known solutions such as Schwarzschild and Kerr metrics and extends the case of rotating spacetimes to hyperbolic configurations. Additionally, we explore the role of Killing tensors in enabling separable metric components, simplifying analyses of geodesic motion and physical phenomena. This framework demonstrates robustness and adaptability for addressing the complexities of axially symmetric spacetimes, paving the way for further applications to Kerr like solutions in General Relativity.