A multishock model for the density variance of anisotropic, highly magnetized, supersonic turbulence

Shocks form the basis of our understanding for the density and velocity statistics of supersonic turbulent flows, such as those found in the cool interstellar medium (ISM). The variance of the density field, σ2ρ/ρ0 , is of particular interest for molecular clouds (MCs), the birthplaces of stars in the Universe. The density variance may be used to infer underlying physical processes in an MC, and parametrizes the star formation (SF) rate of a cloud. However, models for σ2ρ/ρ0 all share a common feature - the variance is assumed to be isotropic. This assumption does not hold when a trans-/sub-Alfvénic mean magnetic field, B0, is present in the cloud, which observations suggest is relevant for some MCs. We develop an anisotropic model for σ2ρ/ρ0, using contributions from hydrodynamical and fast magnetosonic shocks that propagate orthogonal to each other. Our model predicts an upper bound for σ2ρ/ρ0 in the high Mach number (M) limit as small-scale density fluctuations become suppressed by the strong B0. The model reduces to the isotropic σ2ρ/ρ0−M relation in the hydrodynamical limit. To validate our model, we calculate σ2ρ/ρ0 from 12 high-resolution, three-dimensional, supersonic, sub-Alfvénic magnetohydrodynamical (MHD) turbulence simulations and find good agreement with our theory. We discuss how the two MHD shocks may be the bimodally oriented overdensities observed in some MCs and the implications for SF theory in the presence of a sub-Alfvénic B0. By creating an anisotropic, supersonic density fluctuation model, this study paves the way for SF theory in the highly anisotropic regime of interstellar turbulence.