Three-fluid plasmas in star formation I. Magneto-hydrodynamic equations

TL;DR

This paper derives comprehensive magneto-hydrodynamic equations for three-fluid plasmas with arbitrary ionization, including dust grains, to better understand magnetic field evolution during star formation processes.

Contribution

It introduces a general set of equations for three-fluid magnetized plasmas, incorporating dust grains and detailed resistivity calculations, advancing modeling of star formation environments.

Findings

Collisions increase Ohmic resistivity during cloud collapse.

Hall resistivity can be larger when dust carries negative charge.

Ambipolar diffusion occurs on a timescale comparable to dynamical times in protostellar jets.

Abstract

Interstellar magnetic fields influence all stages of the process of star formation, from the collapse of molecular cloud cores to the formation of protostellar jets. This requires us to have a full understanding of the physical properties of magnetized plasmas of different degrees of ionization for a wide range of densities and temperatures. We derive general equations governing the magneto-hydrodynamic evolution of a three-fluid medium of arbitrary ionization, also including the possibility of charged dust grains as the main charge carriers. In a companion paper (Pinto & Galli 2007), we complement this analysis computing accurate expressions of the collisional coupling coefficients. Over spatial and temporal scales larger than the so-called large-scale plasma limit and the collision-dominated plasma limit, and for non-relativistic fluid speeds, we obtain an advection-diffusion for the magnetic field. We derive the general expressions for the resistivities, the diffusion time scales and the heating rates in a three-fluid medium and we use them to estimate the evolution of the magnetic field in molecular clouds and protostellar jets. Collisions between charged particles significantly increase the value of the Ohmic resistivity during the process of cloud collapse, affecting in particular the decoupling of matter and magnetic field and enhancing the rate of energy dissipation. The Hall resistivity can take larger values than previously found when the negative charge is mostly carried by dust grains. In weakly-or mildy-ionized protostellar jets, ambipolar diffusion is found to occur on a time scale comparable to the dynamical time scale, limiting the validity of steady-state and nondissipative models to study the jet's structure.