An Improved Fit to the Density Distribution in Supersonic Isothermal Turbulence

Abstract

The density distribution of supersonic isothermal turbulence plays a critical role in many astrophysical systems. It is commonly approximated by a lognormal distribution with a variance of σs, V2 ≈ (1 + b2 M V2), where s ρ/ρ0, M V is the rms volume-weighted Mach number, and b is a parameter that depends on the driving mechanism, which can be solenoidal (divergence-free), compressive (curl-free), or a mix of both. However, this fit neglects the driving correlation time, τ a, which plays a key role when compressive driving is significant. Here we conduct turbulence simulations spanning a wide range of Mach numbers, driving mechanisms, and τ a values. In the compressive case, σs, V2 is not well fit by the standard expression. Instead, it scales approximately linearly with M V, and its dependence on τ a is σs, V2 ≈ M V [1 + 23(1 + λ a)Θ(1 + λ a)], where λ a (τ a/τ e), τ e is the eddy turnover time, and Θ is the Heaviside step function. Mixed-driven turbulence shows a weak dependence on τ a, and for solenoidally-driven turbulence, σs, V2 ≈ 13M V, which is consistent with the standard expression when M V 8. The volume-weighted mean and skewness also show systematic trends with M V and τ a, deviating from lognormal expectations. The mass-weighted density distribution displays significant broadening and skewness in compressively-driven cases, especially at large τ a/τ e. These results provide a refined framework for modeling astrophysical turbulence.