Quintessence-Chameleon transitions in anisotropic Kiselev model of neutron stars

Abstract

We investigate a chameleon scalar field dynamically interacting with a Kiselev-type metric, where the static anisotropic fluid part of the metric is replaced by a density-dependent scalar field non-minimally coupled to curvature. This construction enables a transition from screened behavior in high-density regions-where the scalar acquires an effective mass mφ1/2-to unscreened quintessence dynamics at large scales, characterized by a critical screening radius r crit mφ-1. By solving the modified TOV equations under spherical symmetry, we show that radial scalar gradients ∂rφ induce pressure anisotropies p r-1 in neutron star envelopes, while deviations from general relativity are suppressed deep in the core r<r crit 0.03\,km without destabilizing it. We further demonstrate that increasing the scalar coupling β enhances scalar energy density, which counteracts anisotropic pressure support and slightly reduces the maximum mass. The resulting (stable) configurations yield maximum mass Mmax≈ 1.750.280\,M and radii R≈11.351.11\,km, consistent with conservative upper and lower bounds from multimessenger observations. Scalar contributions induce a modest suppression in the dimensionless tidal deformability ST GR0.137 at 1.4\,M i.e, 86% suppression compared to typical GR star, falling well within the LIGO/Virgo range 701.4 580. These results demonstrate that environmentally screened scalar fields can dynamically generate anisotropies and modify neutron star structure without violating current astrophysical bounds. In particular, percent-level deviations in compactness and tidal response provide falsifiable signatures of short-range scalar forces, offering a novel target for next-generation GW and multimessenger surveys.