Relativisitic non-pascalian fluid as a density contribution

Anisotropy of local pressure distribution and dissipation are essential in understanding the evolution of the internal structure of compact objects and their observable characteristics. In this work, we reinterpret local pressure anisotropy in relativistic stellar structures as a contribution to the energy density. This approach allows the modelling of any anisotropic equation of state in self-gravitating systems by treating anisotropy as a contribution. We demonstrate that this approach provides more realistic stellar models that meet essential physical criteria, such as mass-radius relationships and stability conditions. The results are compared to observational data, particularly the inferred compactness values for pulsars PSR J0740+6620 and PSR J0030+0451, showing that anisotropic and isotropic models can represent these objects. We further explore how dissipation, such as temperature gradients, influences radial pressure and show that it can be modelled similarly to anisotropy.