Reassessing the Statistical Necessity of Stellar Velocity Anisotropy in Strong-Lensing Cosmology with Lens-by-Lens Photometric Constraints

Abstract

The stellar orbital anisotropy parameter (β ani) is a persistent systematic uncertainty in galaxy-scale strong gravitational lensing (SGL) cosmology. Typically fixed to isotropy or a local prior, it frequently degenerates with the lens density profile. We demonstrate this apparent redundancy largely arises from incomplete photometric constraints. We cross-matched 130 SGL systems with the Pantheon+ SN~Ia compilation, constructing a strictly matched sample of 107 SGL-SN pairs using a 5\% comoving-distance tolerance. Assuming a flat universe (Ωk = 0), the distance ratio is derived from apparent magnitude differences between paired SNe~Ia, eliminating H0 and absolute magnitude dependence without fitting explicit dark-energy models. To break the kinematic degeneracy, we incorporate lens-by-lens luminosity density slopes (δi) from high-resolution imaging. Adopting the quasi-model-independent P2 redshift-evolutionary framework (γ(z) = γ0 + γz z), we find very strong statistical evidence for a free β ani. Fixing β ani to isotropy (β=0) or a local prior (β=0.18) is strongly disfavored (Δ = 14.2 and 48.9) and artificially inflates intrinsic scatter. A complementary P3 framework (γ(z,Σ) = γ0 + γz z + γs 10Σ) confirms these penalties (Δ = 13.5 and 49.1). Across all P2 variants, we consistently detect a negative redshift evolution of the density slope (γz ≈ -0.42 to -0.46; 1.5-2.0σ), indicating ETG density profiles become shallower at higher redshifts. We conclude that when individual photometric constraints are incorporated, β ani is statistically required as a free parameter to prevent severe dynamical modeling biases.