Strong Gravitational Lensing in the Continuum Field Entropy Framework: Optical Retardation and the Shear-Thickening Field

**Preprint | Continuum Field Entropy Empirical Validation Series** We present a novel resolution to the missing mass problem in strong gravitational lensing using the Continuum Field Entropy (CFE) framework. Standard cosmological models rely on non-baryonic Dark Matter to explain the massive Einstein rings observed around dense elliptical galaxies. In the CFE framework, the vacuum is modeled as a non-linear elastic field where fundamental parameters act as dynamic thermodynamic states dependent on local topological tension. Using a hierarchical Hamiltonian Monte Carlo (HMC) inference engine on a representative sample of Sloan Lens ACS (SLACS) lenses, we demonstrate that the high-density, turbulent cores of massive ellipticals trigger a “shear-thickening” of the field. This phase shift raises the Optical Retardation Coefficient (₎₏ₓ) to 0. 58, severely amplifying optical retardation. Our purely baryonic model predicts the observed Einstein rings with complete credible interval overlap, structurally eliminating the need for Dark Matter halos while naturally breaking the mass-sheet degeneracy. **Project Integration: **This document is a standalone validation report. The underlying universal field equations, foundational axioms, and the complete multi-disciplinary validation framework can be found in the primary master manuscript (DOI: 10. 5281/zenodo. 20631794).