Title: Relaxed hydrodynamic theory of electrically driven non-equilibrium steady states

Abstract: Hydrodynamics, as an effective theory capturing long-wavelength and late-time dynamics around thermal equilibrium states, finds applications in diverse physical systems, ranging from electron flow in metals, to ocean wave propagation, traffic flow, bacterial motion and the quark-gluon plasma. On the other hand, non-equilibrium steady states (NESS), characterized by a stationary flow of energy or matter in the presence of a driving force, are pervasive in nature but they present significant challenges to the foundational principles of statistical physics, as it is generally unclear if and how they satisfy the axiomatic assumptions of thermodynamics. The capability of hydrodynamics to accurately describe slow and long-wavelength fluctuations around a NESS remains an open question. In this study, we provide positive evidence by specifically addressing electrically driven non-equilibrium charged steady states. Our approach involves introducing gapped modes and extending the effective description into a relaxed hydrodynamic theory (RHT). Leveraging the gauge-gravity duality as a tool for controlled computations within non-equilibrium systems, we establish an ultraviolet complete model for these NESS that confirms the validity of our RHT. In summary, our findings present a concrete realization of a RHT applicable to a NESS. This expands the regime of validity of hydrodynamics beyond thermal equilibrium, offering valuable insights into the dynamics of non-equilibrium systems.