This work proposes a new mechanism for the internal evolution of rotating black holes based on a resonant matter–antimatter interaction triggered by magnetic-moment reversal. In the ultra-dense quark–electron plasma that forms during gravitational collapse, repeated weak interactions suppress the usual s-wave annihilation channel. Instead, reversed magnetic moments and S-wave resonance conditions create a vacuum-mediated inflow channel that re-centers antimatter probability density toward the core. Once the S-wave resonance is established, the system transitions into a vacuum-resonant core — a low-density, phase-structured region supported not by matter but by coherent vacuum-field coupling. This core naturally explains observed central dimming and the stable jet–counterjet symmetry in supermassive black holes such as M87*. The model connects microscopic quark–electron processes with macroscopic jet formation through a unified physical framework. The resonant vacuum core acts as the seed for a bidirectional conduit. Locally, a cavity-like structure can form on timescales of weeks to years, while global disk–jet restructuring may take 10³–10⁶ years to evolve toward a wormhole-like two-sided configuration. The mechanism further explains why systems such as Sgr A* lack extended jets: electromagnetic pressure dominates over gravitational binding, producing a recycled wormhole-like equilibrium state. This study provides a coherent microphysical basis for jet symmetry, central transparency, oscillatory behavior, and long-term evolution in rotating black holes, linking quantum-scale resonance effects to observable astrophysical structures.
Kim Eun-Seob (Sat,) studied this question.
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