📝 SummarXiv

Abstract

Turbulent radiative mixing layers (TRMLs), where shear-driven turbulence between dense and diffuse phases produces intermediate-temperature gas with short cooling times, are ubiquitous in the interstellar and circumgalactic media. Drawing an analogy with Reynolds' decomposition, we perform a quasi-steady-state analysis of TRMLs, separating fields into mean and turbulent components. In the quasi-isobaric TRML, upstream gas cools and compresses before streamwise momentum is fully mixed across the shear layer, which exhibits the expected negative turbulent shear stress $R_{xz}$ that steadily spreads into the cold phase. The thermal pressure reaches a minimum within the TRML, compensated by a positive vertical compressive stress $R_{zz}$. The sum of upstream ram and thermal pressures balances the downstream thermal pressure. Radiative losses are offset by enthalpy dissipation, with a negative turbulent heat flux $Q_{z}$ indicating thermal transport within the TRML. The volume-averaged temperature profile is well fit by a tanh function -- an emergent property that, for the first time, enables a predictive theory for TRMLs consistent with numerical experiments, including the universality of their temperature-dependent emissivity distributions.