Local Simulations of MRI turbulence with Meshless Methods

Deng, Hongping; Mayer, Lucio; Latter, Henrik N.; Hopkins, Philip F.; Bai, Xue-Ning

doi:10.3847/1538-4365/ab0957

Cited by 35 publications

(76 citation statements)

References 107 publications

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“…MRI-hr has a weaker Maxwell stress than both grvmhd1 and grvmhd2, which reflects the weaker amplification of the magnetic field relative to the runs in which the dynamo operates. We also note that, α M = 2 M rφ / B 2 ∼ 0.4 in MRI-hr, this being characteristic of resolved MRI simulations (Parkin & Bicknell 2013;Hawley et al 2011;Deng et al 2019).…”

Section: Turbulent Transportsupporting

confidence: 64%

“…Flock et al 2011). The reproduction of this generic feature of the MRI dynamo gives us some confidence that our global simulations can describe the MRI up to some level of accuracy for some period of time (see also Deng et al 2019).…”

Section: Morphology and Spectramentioning

confidence: 75%

“…It must be conceded from the outset that the weak field limit, in particular, is polluted (as in all particle codes) by small-scale (resolution dependent) noise, arising from insufficient div(B) cleaning (Deng et al 2019). Throughout our simulations the domain averaged dimensionless divergence |h * ∇ · B/B| is kept to ∼ 10 −3 , where the angle brackets indicates a domain average and h is the resolution length (Deng et al 2019). But despite this relatively low value, the persistent deviation from solenoidality introduces an artificial magnetic diffusion and low-level magnetic activity on the smallest scales.…”

Section: Numerical Methods and Basic Set-upmentioning

confidence: 99%

“…But despite this relatively low value, the persistent deviation from solenoidality introduces an artificial magnetic diffusion and low-level magnetic activity on the smallest scales. This additional numerical diffusivity may explain some of the decaying MRI behaviour witnessed in Deng et al (2019); it also makes challenging the simulation of weak fields, and the estimation of (kinematic) dynamo growth rates. We hence limit ourselves to stronger field initialisations, and keep in mind the enhanced numerical resistivity exhibited by these simulations.…”

Section: Numerical Methods and Basic Set-upmentioning

confidence: 99%

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Global Simulations of Self-gravitating Magnetized Protoplanetary Disks

Deng

Mayer²,

Latter

2020

ApJ

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In the early stages of a protoplanetary disk, when its mass is a significant fraction of its star's, turbulence generated by gravitational instability (GI) should feature significantly in the disk's evolution. At the same time, the disk may be sufficiently ionised for magnetic fields to play some role in the dynamics. Though usually neglected, the impact of magnetism on the GI may be critical, with consequences for several processes: the efficiency of accretion, spiral structure formation, fragmentation, and the dynamics of solids. In this paper, we report on global three-dimensional magnetohydrodynamical simulations of a self-gravitating protoplanetary disk using the meshless finite mass (MFM) Lagrangian technique. We confirm that GI spiral waves trigger a dynamo that amplifies an initial magnetic field to nearly thermal amplitudes (plasma β < 10), an order of magnitude greater than that generated by the magnetorotational instability alone. We also determine the dynamo's nonlinear back reaction on the gravitoturbulent flow: the saturated state is substantially hotter, with an associated larger Toomre parameter and weaker, more 'flocculent' spirals. But perhaps of greater import is the dynamo's boosting of accretion via a significant Maxwell stress; mass accretion is enhanced by factors of several relative to either pure GI or pure MRI. Our simulations use ideal MHD, an admittedly poor approximation in protoplanetary disks, and thus future studies should explore the full gamut of non-ideal MHD. In preparation for that, we exhibit a small number of Ohmic runs that reveal that the dynamo, if anything, is stronger in a non-ideal environment. This work confirms that magnetic fields are a potentially critical ingredient in gravitoturbulent young disks, possibly controlling their evolution, especially via their enhancement of (potentially episodic) accretion.

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Section: Turbulent Transportsupporting

confidence: 64%

Section: Morphology and Spectramentioning

confidence: 75%

Section: Numerical Methods and Basic Set-upmentioning

confidence: 99%

Section: Numerical Methods and Basic Set-upmentioning

confidence: 99%

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Global Simulations of Self-gravitating Magnetized Protoplanetary Disks

Deng

Mayer²,

Latter

2020

ApJ

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“…The angular momentum barrier is thus particularly strong for SMSs. Two mechanisms might allow for efficient angular momentum loss in the accretion process: gravitational torques (Begelman et al, 2006;Wise et al, 2008; and magnetic fields (Pandey et al, 2019;Deng et al, 2019Deng et al, , 2020. Supermassive accretion discs are highly gravitationally unstable, and departures from axial symmetry are pronounced.…”

Section: Rotation In Smssmentioning

confidence: 99%

Formation of the First Stars and Black Holes

et al. 2020

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KeywordsAbstract We review the current status of knowledge concerning the early phases of star formation during cosmic dawn. This includes the first generations of stars forming in the lowest mass dark matter halos in which cooling and condensation of gas with primordial composition is possible at very high redshift (z > 20), namely metal-free Population III stars, and the first generation of massive black holes forming at such early epochs, the socalled black hole seeds. The formation of black hole seeds as end states of the collapse of Population III stars, or via direct collapse scenarios, is discussed. In particular, special emphasis is given to the physics of supermassive stars as potential precursors of direct collapse black holes, in light of recent results of stellar evolution models, and of numerical simulations of the early stages of galaxy formation. Furthermore, we discuss the role of the cosmic radiation produced by the early generation of stars and black holes at high redshift in the process of reionization.

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Future Simulations of Tidal Disruption Events

et al. 2020

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Tidal disruption events involve numerous physical processes (fluid dynamics, magnetohydrodynamics, radiation transport, self-gravity, general relativistic dynamics) in highly nonlinear ways, and, because TDEs are transients by definition, frequently in non-equilibrium states. For these reasons, numerical solution of the relevant equations can be an essential tool for studying these events. In this chapter, we present a summary of the key problems of the field for which simulations offer the greatest promise and identify the capabilities required to make progress on them. We then discuss what has been-and what cannot be-done with existing numerical methods. We close with an overview of what methods now under development may do to expand our ability to understand these events.

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Local Simulations of MRI turbulence with Meshless Methods

Cited by 35 publications

References 107 publications

Global Simulations of Self-gravitating Magnetized Protoplanetary Disks

Global Simulations of Self-gravitating Magnetized Protoplanetary Disks

Formation of the First Stars and Black Holes

Future Simulations of Tidal Disruption Events

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