Litcius/Paper detail

Rapid elimination of small dust grains in molecular clouds

Kedron Silsbee, Alexei V. Ivlev, Olli Sipilä, Paola Caselli, Bo Zhao

2020Astronomy and Astrophysics35 citationsDOIOpen Access PDF

Abstract

We argue that impact velocities between dust grains with sizes of less than ∼0.1 μ m in molecular cloud cores are dominated by drift arising from ambipolar diffusion. This effect is due to the size dependence of the dust coupling to the magnetic field and the neutral gas. Assuming perfect sticking in collisions up to ≈50 m s −1 , we show that this effect causes rapid depletion of small grains, consistent with starlight extinction and IR and microwave emission measurements, both in the core center ( n ∼ 10 6 cm −3 ) and envelope ( n ∼ 10 4 cm −3 ). The upper end of the size distribution does not change significantly if only velocities arising from this effect are considered. We consider the impact of an evolved grain-size distribution on the gas temperature, and argue that if the depletion of small dust grains occurs as expected from our model, then the cosmic ray ionization rate must be well below 10 −16 s −1 at a number density of 10 5 cm −3 .

Topics & Concepts

PhysicsAstrophysicsAmbipolar diffusionMolecular cloudExtinction (optical mineralogy)Cosmic dustInterstellar mediumIonizationEnvelope (radar)InfraredDiffusionOptical depthStar formationParticle-size distributionCosmic rayLuminosityInterstellar cloudCore (optical fiber)Magnetic fieldMicrowaveAtmospheric sciencesNumber densityAsymmetryAstronomyCosmic microwave backgroundH II regionCoupling (piping)Field (mathematics)Interplanetary dust cloudAstrophysics and Star Formation StudiesDust and Plasma Wave PhenomenaOptical properties and cooling technologies in crystalline materials