Relativistic hydrodynamics with phase transition

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Abstract Assessing the applicability of hydrodynamic expansions close to phase transition points is crucial from either theoretical or phenomenological points of view. We explore this within the gauge/gravity duality, using the Einstein–Klein–Gordon model, a bottom-up string theory construction. This model incorporates a parameter, $$B_4$$ B 4 , that simulates different types of phase transitions in the strongly coupled field theory existing at the boundary. We thoroughly examine the thermodynamics and dynamics of time-dependent, linearized perturbations in the spin-2, spin-1, and spin-0 sectors. Our findings suggest that ‘hydrodynamic series breakdown near transition points” is valid exclusively for second-order phase transitions, not for crossovers or first-order phase transitions. Additionally, we observe that the high-temperature and low-temperature limits of the radius of convergence for the hydrodynamic series ( $$q^2_c$$ q c 2 ) are equal. We also discover that the relationship $$(\text {Max}|q^2_c|)_{\text {spin-2}}< (\text {Max}|q^2_c|)_{\text {spin-0}} < (\text {Max}|q^2_c|)_{\text {spin-1}}$$ ( Max | q c 2 | ) spin-2 < ( Max | q c 2 | ) spin-0 < ( Max | q c 2 | ) spin-1 is consistent for different spin sectors, regardless of the phase transition type. At the chaos point, we observe the emergence of pole-skipping behavior for both gravity and scalar perturbations at $$\omega _n = -2\pi T n i$$ ω n = - 2 π T n i . Lastly, comparing the chaos momentum with $$q^2_c$$ q c 2 , we find that $$q^2_{ps} < q^2_c$$ q ps 2 < q c 2 , except for extremely high temperatures.