Black Hole Mystery Solved by New Physics

A groundbreaking physics framework reveals why Kerr-Newman black holes and electrons share identical gyromagnetic ratios—twice the classical value—through a unified approach to gravity and quantum theory. This stems from a deterministic matrix dynamics at the Planck scale, where space-time and matter emerge from fundamental 'aikyons'.

In this theory, aikyons combine gravitational and fermionic aspects without reference to classical time, evolving in Connes time. By coarse-graining the dynamics, researchers derived emergent space-time, quantum theory, and general relativity. The inclusion of Yang-Mills gauge fields via modified Dirac operators allows for unification, showing that spontaneous localization in entangled systems produces classical gravity coupled to gauge fields and particles.

The key insight explains the gyromagnetic ratio match: both black holes and Dirac fermions arise from similar underlying structures in the matrix dynamics, where mass and charge localization occur concurrently. This s traditional separations between gravity and quantum mechanics, offering a path to reconcile them.

Span quantum computing, where non-perturbative gravitational effects could influence qubit behavior, and fundamental physics, by providing a testable framework for emergent space-time. The work underscores that macroscopic objects and particles share deeper connections than previously thought.

Source: Singh, T.P., Pandey, A., & MS, M. (2020). Why does the Kerr-Newman black hole have the same gyromagnetic ratio as the electron? arXiv:2006.05392v1 [gr-qc].