Smooth Signature Change as a Mechanism for Singularity Avoidance in BTZ Black Holes
Abstract
Spacetime singularities represent a fundamental challenge in classical general relativity, prompting investigations into mechanisms that could resolve or avoid them. The paradigm of signature change, where the metric transitions from Lorentzian to Euclidean signature across the horizon, offers a geometric approach to singularity resolution. However, previous implementations based on the discontinuous sign function (r) encounter mathematical inconsistencies in distributional curvature and lead to complex-valued metrics in regular coordinate systems. In this work, we introduce a novel, mathematically rigorous framework for signature-changing black holes by replacing (r) with a smooth, real transition function Sδ(r) = [(r-rh)/δ]. We develop this framework within the analytically tractable (2+1)-dimensional Bañados-Teitelboim-Zanelli (BTZ) geometry. The resulting metric is globally smooth and real for any δ> 0. We prove it satisfies Rμν=0 identically, confirming it as a vacuum solution without surface layers. Curvature invariants remain finite everywhere. Geodesic analysis reveals that radially infalling observers require infinite proper time to reach the horizon, implementing the atemporality mechanism quantitatively. We further establish the physical robustness of the solution by demonstrating its linear stability against gravitational perturbations, well-defined propagation of quantum scalar fields, and preservation of standard BTZ thermodynamics for external observers. Our smooth-transition framework resolves the foundational issues of prior distributional approaches and provides a consistent, computationally tractable model for signature change as a mechanism for classical singularity avoidance.
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