We propose a phenomenological framework termed Vortical Constraint Algebra (VCA), intended as an effective cross-scale gauge approach for analyzing geometrodynamic phase invariants and covariant saturation. This framework explores a potential mechanism to account for the non-dissipative harmonic phase invariants observed across disparate astrophysical scales, particularly in the gravitational lensing system Q2237+0305 (Huchra’s Lens) and core-collapse supernovae orientations. Rather than extending the dark sector with ad hoc particles, VCA models high-density angular momentum environments via a constrained 5-dimensional spacetime-frequency manifold M x F. By deforming the canonical commutation relations with a non-zero Vorticity Tensor Ωμν , we derive an algebraic metric-stiffening effect attributed to a microphysical substrate of Primordial Elementary Whirlings (PEWs). VCA is presented as a framework that recovers General Relativity in low-vorticity regimes, maintaining consistency with standard Einsteinian dynamics and local energy-momentum conservation laws. This work serves as the theoretical companion to the study Cross-Scale Astrophysical Phase Invariants and Metric Anchoring via the Vortical Constraint Algebra (VCA), which discusses the implementation of these algebraic constraints in modeling observed galactic and stellar phase locks.
Chiaramonte et al. (Thu,) studied this question.
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