Are the Formation and Abundances of Metal-poor Stars the Result of Dust Dynamics?

Monthly Notices of the Royal Astronomical Society

2017

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We study the dynamics of large, charged dust grains in turbulent giant molecular clouds (GMCs). Massive dust grains behave as aerodynamic particles in primarily neutral dense gas, and thus are able to produce dramatic small-scale fluctuations in the dust-to-gas ratio. Hopkins & Lee (2016) directly simulated the dynamics of neutral dust grains in super-sonic MHD turbulence, typical of GMCs, and showed that the dust-to-gas fluctuations can exceed factor ∼ 1000 on small scales, with important implications for star formation, stellar abundances, and dust behavior and growth. However, even in primarily neutral gas in GMCs, dust grains are negatively charged and Lorentz forces are non-negligible. Therefore, we extend our previous study by including the effects of Lorentz forces on charged grains (in addition to drag). For small charged grains (sizes 0.1 µm), Lorentz forces suppress dust-to-gas ratio fluctuations, while for large grains (sizes 1 µm), Lorentz forces have essentially no effect, trends that are well explained with a simple theory of dust magnetization. In some special intermediate cases, Lorentz forces can enhance dust-gas segregation. Regardless, for the physically expected scaling of dust charge with grain size, we find the most important effects depend on grain size (via the drag equation) with Lorentz forces/charge as a second-order correction. We show that the dynamics we consider are determined by three dimensionless numbers in the limit of weak background magnetic fields: the turbulent Mach number, a dust drag parameter (proportional to grain size) and a dust Lorentz parameter (proportional to grain charge); these allow us to generalize our simulations to a wide range of conditions.

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The dynamics of charged dust in magnetized molecular clouds

Lee

Monthly Notices of the Royal Astronomical Society

2017

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“…30 As discussed in Paper II, the RDI could be an important part of observed phenomena ranging from the well-studied clumpiness, substructure, and turbulence in the dusty AGN 'torus' (see e.g. Krolik & Begelman 1988;Nenkova et al 2008;Mor, Netzer & Elitzur 2009;Hönig & Kishimoto 2010, and references therein), time variability in AGN dust obscuration (McKernan & Yaqoob 1998;Risaliti, Elvis & Nicastro 2002), AGN winds driven by radiation pressure on dust (Murray et al 2005;Elitzur & Shlosman 2006;Miller, Turner & Reeves 2008;Wada, Papadopoulos & Spaans 2009;Roth et al 2012), observed dust-gas segregation in GMCs (Padoan et al 2006) and abundance anomalies sourced by these (Hopkins 2014;Hopkins & Conroy 2017), dust growth and coagulation (believed to occur primarily in the cold, dense ISM; Draine 2003 and references therein), dust chemistry/cooling physics critical for star formation and formation of complex organic compounds and molecules (Goldsmith & Langer 1978;Dopcke et al 2013;Chiaki et al 2014;Ji, Frebel & Bromm 2014), radiation-pressure-driven outflows from massive stars (Murray et al 2005;Krumholz, Klein & McKee 2007;Hopkins, Quataert & Murray 2011;Grudić et al 2016), and thermal regulation of proto-star formation via heating dust in coupled dust-gas cores (Guszejnov, Krumholz & Hopkins 2016).…”

Section: Sne Ejectamentioning

confidence: 99%

Ubiquitous instabilities of dust moving in magnetized gas

Monthly Notices of the Royal Astronomical Society

2018

Squire & Hopkins showed that coupled dust-gas mixtures are generically subject to 'resonant drag instabilities' (RDIs), which drive violently growing fluctuations in both. But the role of magnetic fields and charged dust has not yet been studied. We therefore explore the RDI in gas that obeys ideal MHD and is coupled to dust via both Lorentz forces and drag, with an external acceleration (e.g. gravity, radiation) driving dust drift through gas. We show this is always unstable, at all wavelengths and non-zero values of dust-togas ratio, drift velocity, dust charge, 'stopping time' or drag coefficient (for any drag law), or field strength; moreover, growth rates depend only weakly (sub-linearly) on these parameters. Dust charge and magnetic fields do not suppress instabilities, but give rise to a large number of new instability 'families,' each with distinct behavior. The 'MHD-wave' (magnetosonic or Alfvén) RDIs exhibit maximal growth along 'resonant' angles where the modes have a phase velocity matching the corresponding MHD wave, and growth rates increase without limit with wavenumber. The 'gyro' RDIs are driven by resonances between drift and Larmor frequencies, giving growth rates sharply peaked at specific wavelengths. Other instabilities include 'acoustic' and 'pressurefree' modes (previously studied), and a family akin to cosmic ray instabilities that appear when Lorentz forces are strong and dust streams super-Alfvénically along field lines. We discuss astrophysical applications in the warm ISM, circum-galactic medium/inter-galactic medium (CGM/IGM), H II regions, SNe ejecta/remnants, Solar corona, cool-star winds, GMCs, and AGN.

“…They may fundamentally alter the ability of radiation pressure from massive stars to drive outflows and source local turbulence (a subject of considerable interest and controversy; see Murray et al 2005;Thompson et al 2005;Krumholz et al 2007;Schartmann et al 2009;Hopkins et al 2011Hopkins et al , 2013Hopkins et al , 2014Guszejnov et al 2016;Grudić et al 2018). They will also directly source dust-togas fluctuations, which can in turn drive abundance anomalies in next-generation stars (Hopkins 2014;Hopkins & Conroy 2017), as well as altering the dust growth, chemistry, and cooling physics of the clouds (Goldsmith & Langer 1978;Dopcke et al 2013;Ji et al 2014;Chiaki et al 2014).…”

Section: Astrophysical Applicationsmentioning

confidence: 99%

The resonant drag instability (RDI): acoustic modes

Monthly Notices of the Royal Astronomical Society

2018

Recently, Squire & Hopkins (2017) showed any coupled dust-gas mixture is subject to a class of linear "resonant drag instabilities" (RDI). These can drive large dust-to-gas ratio fluctuations even at arbitrarily small dust-to-gas mass ratios µ. Here, we identify and study both resonant and new non-resonant instabilities, in the simple case where the gas satisfies neutral hydrodynamics and supports acoustic waves (ω 2 = c 2 s k 2 ). The gas and dust are coupled via an arbitrary drag law and subject to external accelerations (e.g. gravity, radiation pressure). If there is any dust drift velocity, the system is unstable. The instabilities exist for all dust-to-gas ratios µ and their growth rates depend only weakly on µ around resonance, as ∼ µ 1/3 or ∼ µ 1/2 (depending on wavenumber). The behavior changes depending on whether the drift velocity is larger or smaller than the sound speed c s . In the supersonic regime a "resonant" instability appears with growth rate increasing without limit with wavenumber, even for vanishingly small µ and values of the coupling strength ("stopping time"). In the subsonic regime non-resonant instabilities always exist, but their growth rates no longer increase indefinitely towards small wavelengths. The dimensional scalings and qualitative behavior of the instability do not depend sensitively on the drag law or equation-of-state of the gas. The instabilities directly drive exponentially growing dust-togas-ratio fluctuations, which can be large even when the modes are otherwise weak. We discuss physical implications for cool-star winds, AGN-driven winds and torii, and starburst winds: the instabilities alter the character of these outflows and could drive clumping and/or turbulence in the dust and gas.