Aditya Singh, Ashes Modak, Binata Panda

In this work, we examine the onset of thermodynamic chaos in Hayward AdS black holes with string fluids, emphasizing the effects of temporal and spatially periodic perturbations. We apply Melnikov's approach to examine the perturbed Hamiltonian dynamics and detect the onset of chaotic behavior within the spinodal regime of the $(P-v)$ plot. In the case of temporal perturbations induced by thermal quenches, chaos occurs for perturbation amplitude $\gamma$ exceeding a critical threshold that can be determined by charge $q$ and the string fluid parameter. From the equation of state of the black hole, a general condition can be established indicating that under temporal perturbations, the existence of charge is an essential prerequisite for chaos. In this regime, neutral Hayward black holes do not exhibit chaotic dynamics. However, regardless of the presence of charge, spatial perturbations result in chaotic behavior. The nonlinear interplay between the regularized core geometry and string fluids drives the formation of homoclinic and heteroclinic orbits in phase space, validating the persistence of chaos. The results obtained in this work, highlights the role of nonlinear matter fields and curvature regularization mechanisms in governing thermodynamic instability and the onset of chaos in Hayward black holes in AdS.