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This research aims to extend the isotropic gravastar model by introducing anisotropy while maintaining physical consistency.

March 28, 2026Open Access

Relativistic formulation and physical viability of anisotropic analytic gravastars

Key Points

This research aims to extend the isotropic gravastar model by introducing anisotropy while maintaining physical consistency.
Developed an anisotropic version of the Imran class gravastar model.
Ensured regularity at the center and smooth transition to Schwarzschild spacetime.
Enforced conditions for vanishing anisotropy at the center and surface.
Analyzed energy conditions and stability diagnostics.
Equilibrium configurations satisfy all energy conditions and stability criteria.
Mass-radius domain aligns with that of neutron star-like compact objects.
The isotropic gravastar solution is smoothly recovered in the limit of zero anisotropy.

Abstract

Abstract We develop a fully consistent anisotropic extension of the Imran class ICG (Isotropic Compact Gravastar) model within general relativity. A geometry-coupled anisotropy is introduced at the exact equation level, ensuring regularity at the center, smooth matching to the exterior Schwarzschild spacetime, and the absence of thin shells. A controlled option enforces vanishing anisotropy at both the center and the surface. The resulting equilibrium configurations satisfy energy conditions, causality, compactness bounds, and stability diagnostics. The admissible mass–radius domain overlaps that of neutron star like compact objects, and the isotropic ICG solution is recovered smoothly in the zero-anisotropy limit. These results provide a robust anisotropic gravastar background for future rotational and tidal analyses.

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Relativistic formulation and physical viability of anisotropic analytic gravastars

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