Turbulence in cascading: Origin of the variance and skewness of density function

Abstract

Turbulent systems typically exhibit log-normal volume density probability density functions (PDFs) on the s = ρ scale, with their variance (σ2) and skewness (τ) empirically regulated by the Mach number (M). In this work, we explain both the σ2--M and τ--M relationships from a thermodynamic and cascade perspective. Entropy conservation within the compressive modes yields the fiducial relation σ2 = (1 + M2), while deviations from a monotonic energy cascade modify this law into a dilogarithm function. Although skewness exerts a negligible impact on the global σ2--M scaling, the characteristic skewness parameter τ obeys a similar scaling law, τ (1 + M2). We demonstrate that the asymmetric wings of the global density PDF originate from underlying low-s and high-s skewed kernels. These kernels are governed by two distinct structural redistribution mechanisms -- the mass-fraction and volume-fraction approaches -- which exhibit a profound duality symmetry. Crucially, the high-s skewed kernels are physically realizable and closely mirror the gravity-driven power-law tails of column density PDFs observed in molecular clouds.