Ion Alfvén velocity fluctuations and implications for the diffusion of streaming cosmic rays

Beattie, James A.; Krumholz, Mark R.; Federrath, Christoph; Sampson, Matt; Crocker, Roland M.

doi:10.48550/arxiv.2203.13952

Cited by 3 publications

(8 citation statements)

References 120 publications

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“…However, there is less studies, and less agreement in the literature regarding the behaviour of 𝜅 with M A0 in the M A0 1 regime. Here a number of authors report 𝜅 ∼ M 4 𝐴 (Yan & Lazarian 2008;Xu & Yan 2013;Cohet & Marcowith 2016) 9 , i.e., the diffusion scaling exactly with the magnetic field variance (Beattie et al 2022). While the direction of the scaling of 𝜅 for sub-Alfvénic turbulence found in these simulations is qualitatively consistent with our findings, we find a vastly different scaling, 𝜅 ∼ M −1 A0 , which is closer to results from Casse et al (2001).…”

Section: Comparison To Previous Resultssupporting

confidence: 89%

“…Because 𝜎 2 𝑠 ∼ ln(1 + M 2 ) (Federrath et al 2008;Federrath et al 2010b;Molina et al 2012;Beattie et al 2021b), this explains the scatter in M that we see in the top left panel of Figure 7. We postpone a more detailed comparison between Beattie et al (2022) theory and our results for a future study.…”

Section: Anisotropic Regimementioning

confidence: 95%

“…Gas density fluctuations in compressible turbulence are extremely inhomogenous, and are not isotropic when the large-scale field is strong 7 . Since 𝑣 str ∝ 𝐵/ √ 𝜌, inhomogeneities in the gas density can produce macroscopic diffusion in the positions of SCRs, regardless of the value of M A0 , as temporally and/or spatially separated SCRs populations experience different density fluctuations along their trajectories (Beattie et al 2022). For M A0 < 1 turbulence, when the magnetic field fluctuations are negligible, Beattie et al (2022) showed that, in the absence of strong advection, density fluctuations formed from gas flows along the magnetic fields solely determine the macroscopic diffusion in ℓ .…”

Section: Density Fluctuationsmentioning

confidence: 99%

“…Since 𝑣 str ∝ 𝐵/ √ 𝜌, inhomogeneities in the gas density can produce macroscopic diffusion in the positions of SCRs, regardless of the value of M A0 , as temporally and/or spatially separated SCRs populations experience different density fluctuations along their trajectories (Beattie et al 2022). For M A0 < 1 turbulence, when the magnetic field fluctuations are negligible, Beattie et al (2022) showed that, in the absence of strong advection, density fluctuations formed from gas flows along the magnetic fields solely determine the macroscopic diffusion in ℓ . For M A0 > 1, both the 𝐵-field fluctuations and correlations between the 𝐵 and 𝜌 grow and contribute to setting the fluctuations in 𝑣 str .…”

Section: Density Fluctuationsmentioning

confidence: 99%

“…As 𝜅 ⊥ is independent of 𝜒 in this regime, with a systematic scatter set by M (see top left panel of Figure 7) this shows that 𝜅 ∝ 𝑣 str,0 /2. In this regime Beattie et al (2022) finds that 𝜅 ∝ (1/4)𝜎 2 𝑠 𝑣 str,0 ℓ cor,𝜌/𝜌 0 , where 𝜎 2 𝑠 is the logarithmic gas density variance and ℓ cor,𝜌/𝜌 0 is the gas density correlation scale. By substituting this model into equation 19,…”

Section: Anisotropic Regimementioning

confidence: 99%

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Turbulent diffusion of streaming cosmic rays in compressible, partially ionised plasma

Sampson¹,

Beattie²,

Krumholz³

et al. 2022

Preprint

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Cosmic rays (CRs) are a dynamically important component of the interstellar medium (ISM) of galaxies. The ∼GeV CRs that carry most CR energy and pressure are likely confined by self-generated turbulence, leading them to stream along magnetic field lines at the ion Alfvén speed. However, the consequences of self-confinement for CR propagation on galaxy scales remain highly uncertain. In this paper, we use a large ensemble of magnetohydrodynamical turbulence simulations to quantify how the basic parameters describing ISM turbulence -the sonic Mach number, M (plasma compressibility), Alfvén Mach number, M A0 (strength of the large-scale field with respect to the turbulence), and ionisation fraction by mass, 𝜒 -affect the transport of streaming CRs. We show that the large-scale transport of CRs whose small-scale motion consists of streaming along field lines is well described as a combination of streaming along the mean field and superdiffusion both along (parallel to) and across (perpendicular to) it; M A0 drives the level of anisotropy between parallel and perpendicular diffusion and 𝜒 modulates the magnitude of the diffusion coefficients, while in our choice of units, M is unimportant except in the sub-Alfvénic (M A0 0.5) regime. Our finding that superdiffusion is ubiquitous potentially explains the apparent discrepancy between CR diffusion coefficients inferred from measurements close to individual sources compared to those measured on larger, Galactic scales. Finally, we present empirical fits for the diffusion coefficients as a function of plasma parameters that may be used as sub-grid recipes for global interstellar medium, galaxy or cosmological simulations.

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Section: Comparison To Previous Resultssupporting

confidence: 89%

Section: Anisotropic Regimementioning

confidence: 95%

Section: Density Fluctuationsmentioning

confidence: 99%

Section: Density Fluctuationsmentioning

confidence: 99%

Section: Anisotropic Regimementioning

confidence: 99%

See 3 more Smart Citations

Turbulent diffusion of streaming cosmic rays in compressible, partially ionised plasma

Sampson¹,

Beattie²,

Krumholz³

et al. 2022

Preprint

Self Cite

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Cosmic Ray Interstellar Propagation Tool using Itô Calculus (criptic): software for simultaneous calculation of cosmic ray transport and observational signatures

Krumholz¹,

Crocker²,

Sampson³

2022

Preprint

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We present, the Cosmic Ray Interstellar Propagation Tool using Itô Calculus, a new open-source software package to simulate the propagation of cosmic rays through the interstellar medium and to calculate the resulting observable non-thermal emission. C solves the Fokker-Planck equation describing transport of cosmic rays on scales larger than that on which their pitch angles become approximately isotropic, and couples this to a rich and accurate treatment of the microphysical processes by which cosmic rays in the energy range ∼MeV to ∼PeV lose energy and produce emission. C is deliberately agnostic as to both the cosmic ray transport model and the state of the background plasma through which cosmic rays travel. It can solve problems where cosmic rays stream, diffuse, or perform arbitrary combinations of both, and the coefficients describing these transport processes can be arbitrary functions of the background plasma state, the properties of the cosmic rays themselves, and local integrals of the cosmic ray field itself (e.g., the local cosmic ray pressure or pressure gradient). The code is parallelised using a hybrid OpenMP-MPI paradigm, allowing rapid calculations exploiting multiple cores and nodes on modern supercomputers. Here we describe the numerical methods used in the code, our treatment of the microphysical processes, and the set of code tests and validations we have performed.

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Analytic characterization of sub-Alfvénic turbulence energetics

Skalidis¹,

Tassis²,

Pavlidou³

2022

Preprint

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We calculate the energetics of compressible and sub-Alfvénic turbulence based on the dynamics of coherent cylindrical fluid parcels. We show that parallel and perpendicular magnetic fluctuations are generalized coordinates of the local perturbed Lagrangian of a magnetized fluid, and prove analytically that the bulk of the magnetic energy transferred to kinetic is the energy stored in the coupling between the initial and fluctuating magnetic field, ì 𝐵 0 • 𝛿 ì 𝐵/4𝜋. The analytical relations are consistent with numerical data up to second order terms.

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Ion Alfvén velocity fluctuations and implications for the diffusion of streaming cosmic rays

Cited by 3 publications

References 120 publications

Turbulent diffusion of streaming cosmic rays in compressible, partially ionised plasma

Turbulent diffusion of streaming cosmic rays in compressible, partially ionised plasma

Cosmic Ray Interstellar Propagation Tool using Itô Calculus (criptic): software for simultaneous calculation of cosmic ray transport and observational signatures

Analytic characterization of sub-Alfvénic turbulence energetics

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