Simulating diverse instabilities of dust in magnetized gas

Hopkins, Philip F.; Squire, Jonathan; Seligman, Darryl Z.

doi:10.1093/mnras/staa1046

Cited by 29 publications

(47 citation statements)

References 56 publications

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“…It has been predicted that negatively charged grains may affect the star formation efficiency due to gyroresonance effects with MHD waves propagating inside MCs (Pilipp et al 1987;Nakano 1998;Falceta-Gonçalves et al 2003;Hopkins et al 2020). For instance, Chapman & Wardle (2006) demonstrated that C-type MHD shocks profiles are deeply affected by the presence of a population of charged grains; Pandey & Vladimirov (2019) have recently shown that the Kevin-Helmholz instability in MCs depends on the dust charge density and size distribution; and Wardle (2007) and Pinto et al (2008) derived the modified coefficients for non-ideal MHD effects (Ohmic resistivity, and ambipolar and Hall diffusion) in the presence of charged dust grains.…”

Section: and Ismentioning

confidence: 99%

Formation of Dust Filaments in the Diffuse Envelopes of Molecular Clouds

Beitia-Antero

Castro

Vallejo

2021

ApJ

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The path to understanding star formation processes begins with the study of the formation of molecular clouds. The outskirts of these clouds are characterized by low column densities that allow the penetration of ultraviolet radiation, resulting in a non-negligible ionization fraction and the charging of the small dust grains that are mixed with the gas; this diffuse phase is then coupled to the ambient magnetic field. Despite the general assumption that dust and gas are tightly correlated, several observational and theoretical studies have reported variations in the dust-to-gas ratio toward diffuse and cold clouds. In this work, we present the implementation of a new charged particles module for analyzing the dust dynamics in molecular cloud envelopes. We study the evolution of a single population of small charged grains (0.05 µm) in the turbulent, magnetized molecular cloud envelope using this module. We show that variations in the dust-to-gas ratio arise due to the coupling of the grains with the magnetic field, forming elongated dust structures decoupled from the gas. This emphasizes the importance of considering the dynamics of charged dust when simulating the different phases of the interstellar medium, especially for star formation studies.

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Section: and Ismentioning

confidence: 99%

Formation of Dust Filaments in the Diffuse Envelopes of Molecular Clouds

Beitia-Antero

Castro

Vallejo

2021

ApJ

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“…This effect was seen and diagnosed in detail in the CR streaming-instability simulations of Holcomb & Spitkovsky (2019), where they noted that CRs with an initial drift velocity that is too large (approaching c) are inefficiently self-confined, because the wave scattering only isotropizes particles with one sign of ξ . However, the non-linear saturation of the dust instability presents significant uncertainties; if the saturation is quasi-turbulent in nature, as suggested by the simulations of Seligman, Hopkins & Squire (2019), Hopkins et al (2020c) (albeit in a different regimes), it seems implausible that only one wave polarization would be present in the saturated state. In that case, fluctuations induced by the dust could more efficiently isotropize CRs.…”

Section: Polarizationmentioning

confidence: 99%

“…The most obvious candidate is by exciting some type of turbulence, which scatters dust particles sufficiently to shut off the instability's drive. The simulations of Hopkins et al (2020c) suggest that a simple saturation criterion is when a characteristic turnover time at the scale of interest is equal to the instability growth rate, which leads to an estimate of the power in small scale parallel fluctuations δ B 2 /B 2 ∼ ( /ω A ) 2 , where /ω A is the growth rate of the dust instability normalized by the Alfvén frequency at the chosen scale. This implies the CR diffusivity…”

Section: Enhanced Cosmic Ray Scattering Through Dust-excited Alfvén Wavesmentioning

confidence: 99%

“…turbulent fluctuations of both polarizations) even if one polarization reaches higher amplitude. Unfortunately, the extremely small scales of interest were not directly probed by the simulations of Hopkins et al (2020c) (the 'CGM' simulation approaches similar conditions). Further simulations or more detailed analytic theory are clearly needed, but we proceed anyway for lack of a more accurate estimate.…”

Section: Enhanced Cosmic Ray Scattering Through Dust-excited Alfvén Wavesmentioning

confidence: 99%

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The impact of astrophysical dust grains on the confinement of cosmic rays

Squire

Hopkins

Quataert

et al. 2021

Monthly Notices of the Royal Astronomical Society

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We argue that charged dust grains could significantly impact the confinement and transport of galactic cosmic rays. For sub-GeV to ∼103GeV cosmic rays, small-scale parallel Alfvén waves, which isotropize cosmic rays through gyro-resonant interactions, are also gyro-resonant with charged grains. If the dust is nearly stationary, as in the bulk of the interstellar medium, Alfvén waves are damped by dust. This will reduce the amplitude of Alfvén waves produced by the cosmic rays through the streaming instability, thus enhancing cosmic-ray transport. In well-ionized regions, the dust damping rate is larger by a factor of ∼10 than other mechanisms that damp parallel Alfvén waves at the scales relevant for ∼GeV cosmic rays, suggesting that dust could play a key role in regulating cosmic-ray transport. In astrophysical situations in which the dust moves through the gas with super-Alfvénic velocities, Alfvén waves are rendered unstable, which could directly scatter cosmic rays. This interaction has the potential to create a strong feedback mechanism where dust, driven through the gas by radiation pressure, then strongly enhances the confinement of cosmic rays, increasing their capacity to drive outflows. This mechanism may act in the circumgalactic medium around star-forming galaxies and active galactic nuclei.

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“…Collins 1989), plasma instabilities (e.g. Melrose 1980), or related dust instabilities (Moseley, Seligman, Hopkins & Squire 2019;Hopkins, Squire & Seligman 2020).…”

Section: Introductionmentioning

confidence: 99%

Physical models of streaming instabilities in protoplanetary discs

Squire

Hopkins

2020

Monthly Notices of the Royal Astronomical Society

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We develop simple, physically motivated models for drag-induced dust-gas streaming instabilities, which are thought to be crucial for clumping grains to form planetesimals in protoplanetary disks. The models explain, based on the physics of gaseous epicyclic motion and dust-gas drag forces, the most important features of the streaming instability and its simple generalisation, the disk settling instability. Some of the key properties explained by our models include the sudden change in the growth rate of the streaming instability when the dust-to-gas-mass ratio surpasses one, the slow growth rate of the streaming instability compared to the settling instability for smaller grains, and the main physical processes underlying the growth of the most unstable modes in different regimes. As well as providing helpful simplified pictures for understanding the operation of an interesting and fundamental astrophysical fluid instability, our models may prove useful for analysing simulations and developing nonlinear theories of planetesimal growth in disks.

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Simulating diverse instabilities of dust in magnetized gas

Cited by 29 publications

References 56 publications

Formation of Dust Filaments in the Diffuse Envelopes of Molecular Clouds

Formation of Dust Filaments in the Diffuse Envelopes of Molecular Clouds

The impact of astrophysical dust grains on the confinement of cosmic rays

Physical models of streaming instabilities in protoplanetary discs

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