The density structure and star formation rate of non-isothermal polytropic turbulence

Federrath, Christoph; Banerjee, Supratik

doi:10.1093/mnras/stv180

Cited by 113 publications

(144 citation statements)

References 135 publications

(221 reference statements)

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“…Overall, model predictions seem to match with numerical results up to numerical uncertainties, although more detailed comparisons will be necessary to understand its successes and failures more completely. We finish with an extension to non-isothermal turbulence (illustrating reasonable qualitative agreement with the simulations of Federrath & Banerjee 2015) and a discussion of MHD, before concluding by reiterating the model's main predictions.…”

Section: Introductionmentioning

confidence: 56%

“…(iv) The assumption that the shock width is equal to the sonic scale-while useful as a phenomenological tool for deriving density variance-Mach number relations (Price et al 2011;Padoan & Nordlund 2011;Molina et al 2012;Federrath & Banerjee 2015)is inconsistent with log-normal density statistics. In particular, for isothermal shocks with a density contrast ∼ M 2 , such a model involves all of the mass being concentrated in a single shock, which leads to an unphysically intermittent density distribution.…”

Section: General Considerationsmentioning

confidence: 99%

“…These are crucial for star-formation applications and directly observable in the ISM. However, although there are certain wellestablished results-most importantly the density variance-Mach number relation: that the density distribution is approximately lognormal with a variance that increases with Mach number (Passot & Vázquez-Semadeni 1998;Price et al 2011;Padoan & Nordlund 2011;Molina et al 2012;Federrath & Banerjee 2015;Pan et al 2016)-we lack detailed understanding of many important issues. For example, the power spectrum of density and its variation with Mach number is not well understood (Kim & Ryu 2005;Kritsuk et al 2007;Kowal et al 2007;Konstandin et al 2016).…”

Section: Introductionmentioning

confidence: 99%

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The distribution of density in supersonic turbulence

Squire

Hopkins

2017

Monthly Notices of the Royal Astronomical Society

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We propose a model for the density statistics in supersonic turbulence, which play a crucial role in star-formation and the physics of the interstellar medium (ISM). Motivated by [Hopkins, MNRAS, 430, 1880(2013], the model considers the density to be arranged into a collection of strong shocks of width ∼ M −2 , where M is the turbulent Mach number. With two physically motivated parameters, the model predicts all density statistics for M > 1 turbulence: the density probability distribution and its intermittency (deviation from log-normality), the density variance-Mach number relation, power spectra, and structure functions. For the proposed model parameters, reasonable agreement is seen between model predictions and numerical simulations, albeit within the large uncertainties associated with current simulation results. More generally, the model could provide a useful framework for more detailed analysis of future simulations and observational data. Due to the simple physical motivations for the model in terms of shocks, it is straightforward to generalize to more complex physical processes, which will be helpful in future more detailed applications to the ISM. We see good qualitative agreement between such extensions and recent simulations of non-isothermal turbulence.

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Section: Introductionmentioning

confidence: 56%

Section: General Considerationsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The distribution of density in supersonic turbulence

Squire

Hopkins

2017

Monthly Notices of the Royal Astronomical Society

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“…It is supersonic, magnetized turbulence that determines the density PDF and, in particular, its standard deviation (Padoan et al 1997b;Federrath et al 2008b;Padoan & Nordlund 2011;Price et al 2011;Konstandin et al 2012;Burkhart & Lazarian 2012;Molina et al 2012;Federrath & Banerjee 2015;Nolan et al 2015). A high-density power-law tail can develop as a consequence of gravitational contraction of the dense cores in a cloud (Klessen 2000;Federrath et al 2008aFederrath et al , 2011bKritsuk et al 2011;Federrath & Klessen 2013;Girichidis et al 2014).…”

Section: Density Pdf and Conversion From Twomentioning

confidence: 99%

“…6. THE EFFECTIVE TURBULENT DRIVING Theoretical and numerical studies have shown that the density fluctuations (s r r 0 ) in a turbulent medium correlate with the Mach number () and the driving of the turbulence, which is controlled by the turbulence driving parameter b (Federrath et al 2008bPrice et al 2011;Konstandin et al 2012;Federrath & Banerjee 2015;Nolan et al 2015), . While Equation (8) lists the three special cases (solenoidal, mixed, compressive), the driving parameter can vary continuously in the range   b 1 3…”

Section: The Sonic Scale and Filament Widthmentioning

confidence: 99%

The Link Between Turbulence, Magnetic Fields, Filaments, and Star Formation in the Central Molecular Zone Cloud G0.253+0.016

Federrath

Rathborne

Longmore

et al. 2016

ApJ

176

235

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Star formation is primarily controlled by the interplay between gravity, turbulence, and magnetic fields. However, the turbulence and magnetic fields in molecular clouds near the Galactic center may differ substantially compared to spiral-arm clouds. Here we determine the physical parameters of the central molecular zone (CMZ) cloud G0.253 +0.016, its turbulence, magnetic field, and filamentary structure. Using column density maps based on dust

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Physical Processes in Protoplanetary Disks

Armitage

2019

Saas-Fee Advanced Course

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This review, based on lectures given at the 45th Saas-Fee Advanced Course "From Protoplanetary Disks to Planet Formation", introduces physical processes in protoplanetary disks relevant to accretion and the initial stages of planet formation. After a brief overview of the observational context, I introduce the elementary theory of disk structure and evolution, review the gas-phase physics of angular momentum transport through turbulence and disk winds, and discuss possible origins for the episodic accretion observed in Young Stellar Objects. Turning to solids, I review the evolution of single particles under aerodynamic forces, and describe the conditions necessary for the development of collective gas-particle instabilities. Observations show that disks can exhibit pronounced large-scale structure, and I discuss the types of structures that may form from gas and particle interactions at ice lines, vortices and zonal flows, prior to the formation of large planetary bodies. I conclude with disk dispersal.

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The density structure and star formation rate of non-isothermal polytropic turbulence

Cited by 113 publications

References 135 publications

The distribution of density in supersonic turbulence

The distribution of density in supersonic turbulence

The Link Between Turbulence, Magnetic Fields, Filaments, and Star Formation in the Central Molecular Zone Cloud G0.253+0.016

Physical Processes in Protoplanetary Disks

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