Fuzzy Dark Matter Less-complex Wormhole Structures in Extended Theories of Gravity

Fuzzy dark matter wormhole solutions coupled with anisotropic matter distribution are explored in 4D Einstein-Gauss-Bonnet and $f(R)$ gravity, where $R$ is the Ricci scalar. We derive the shape function for fuzzy wormholes and explore their possible stability. We study the embedding diagrams of the active gravitational mass associated with fuzzy dark matter wormholes by taking a certain shape function. Aiming to highlight the role of Einstein-Gauss-Bonnet and $f(R)$ gravity in the modeling of less complex fuzzy wormhole structures, we evaluate the complexity factor, the conservation equation, and null energy conditions. Our study reinforces more importance of uniformly distributed pressure effects throughout the less complex region than to the emergence of energy density homogeneity in the stability of fuzzy wormholes. It is shown that the active gravitational mass of the fuzzy wormhole structures varies inversely with the radial distance thereby suggesting the breaching of energy conditions at some arena of Einasto index. Furthermore, it is revealed that stable fuzzy dark matter wormhole structures exist in nature in the surroundings of cold dark matter halos and galactic bulges. The important physics understood from our analysis is that in both four-dimensional Einstein-Gauss-Bonnet and $f(R)$ gravity, feasible geometries of fuzzy dark matter wormholes exist naturally in the environments of different galactic haloes.
Comment: 25 pages, 16 figures