Relative distribution of cosmic rays and magnetic fields

Seta, Amit; Shukurov, Anvar; Wood, Toby S.; Bushby, P. J.; Snodin, A. P.

doi:10.1093/mnras/stx2606

Cited by 41 publications

(41 citation statements)

References 56 publications

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“…This further demonstrates that the magnetic field in the saturated stage is less intermittent than that in the kinematic stage. We further compare both terms with the corresponding Gaussian versions obtained by randomizing phases in Fourier space [keeping the exact same magnetic field spectrum but destroying intermittent structures, as done in 35,36,59]. Q nl and Q nl /Q nl−1 are higher for the dynamo generated field in comparison to its randomized Gaussian versions in both the kinematic and saturated stages.…”

Section: Magnetic Intermittencymentioning

confidence: 99%

Saturation mechanism of the fluctuation dynamo at PrM ≥ 1

et al. 2020

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The presence of magnetic fields in many astrophysical objects is due to dynamo action, whereby a part of the kinetic energy is converted into magnetic energy. A turbulent dynamo that produces magnetic field structures on the same scale as the turbulent flow is known as the fluctuation dynamo. We use numerical simulations to explore the nonlinear, statistically steady state of the fluctuation dynamo in driven turbulence. We demonstrate that as the magnetic field growth saturates, its amplification and diffusion are both affected by the back-reaction of the Lorentz force upon the flow. The amplification of the magnetic field is reduced due to stronger alignment between the velocity field, magnetic field, and electric current density. Furthermore, we confirm that the amplification decreases due to a weaker stretching of the magnetic field lines. The enhancement in diffusion relative to the field line stretching is quantified by a decrease in the computed local value of the magnetic Reynolds number. Using the Minkowski functionals, we quantify the shape of the magnetic structures produced by the dynamo as magnetic filaments and ribbons in both kinematic and saturated dynamos and derive the scalings of the typical length, width, and thickness of the magnetic structures with the magnetic Reynolds number. We show that all three of these magnetic length scales increase as the dynamo saturates. The magnetic intermittency, strong in the kinematic dynamo (where the magnetic field strength grows exponentially) persists in the statistically steady state, but intense magnetic filaments and ribbons are more volume-filling.

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Section: Magnetic Intermittencymentioning

confidence: 99%

Saturation mechanism of the fluctuation dynamo at PrM ≥ 1

et al. 2020

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“…However, at low frequencies (typically below a few Figure 4. Test particle simulations of the propagation of cosmic rays in a random magnetic field (figures 2 and 8 in [45]); the particles' Larmor radius is 6% of the correlation length of the magnetic field. Left-hand panel:…”

Section: Synchrotron Intensitymentioning

confidence: 99%

IMAGINE: a comprehensive view of the interstellar medium, Galactic magnetic fields and cosmic rays

Boulanger

Enßlin

Fletcher

et al. 2018

J. Cosmol. Astropart. Phys.

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In this white paper we introduce the IMAGINE Consortium and its scientific background, goals and structure. The purpose of the consortium is to coordinate and facilitate the efforts of a diverse group of researchers in the broad areas of the interstellar medium, Galactic magnetic fields and cosmic rays, and our overarching goal is to develop more comprehensive insights into the structures and roles of interstellar magnetic fields and their interactions with cosmic rays within the context of Galactic astrophysics. The ongoing rapid development of observational and numerical facilities and techniques has resulted in a widely felt need to advance this subject to a qualitatively higher level of self-consistency, depth and rigour. This can only be achieved by the coordinated efforts of experts in diverse areas of astrophysics involved in observational, theoretical and numerical work. We present our view of the present status of this research area, identify its key unsolved problems and suggest a strategy that will underpin our work. The backbone of the consortium is the Interstellar MAGnetic field INference Engine, a publicly available Bayesian platform that employs robust statistical methods to explore the multi-dimensional likelihood space using any number of modular inputs. This tool will be used by the IMAGINE Consortium to develop an interpretation and modelling framework that provides the method, power and flexibility to interfuse information from a variety of observational, theoretical and numerical lines of evidence into a self-consistent and comprehensive picture of the thermal and non-thermal interstellar media. An important innovation is that a consistent understanding of the phenomena that are directly or indirectly influenced by the Galactic magnetic field, such as the deflection of ultra-high energy cosmic rays or extragalactic backgrounds, is made an integral part of the modelling. The IMAGINE Consortium, which is informal by nature and open to new participants, hereby presents a methodological framework for the modelling and understanding of Galactic magnetic fields that is available to all communities whose research relies on a state of the art solution to this problem.

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“…particles which are placed randomly within the domain with same speed but random velocity directions. We confirm that the particles diffuse by calculating the time-steady diffusion coefficient [5,74]. Once the diffusion sets in, we calculate the coordinates of each particle modulo the length of the box (2π), divide the entire domain into (512) 3 smaller cubes and count the number of particles in each cube to obtain the particle number density as a function of position and time.…”

Section: Cosmic Rays As Test-particlesmentioning

confidence: 91%

Revisiting the Equipartition Assumption in Star-Forming Galaxies

Seta¹,

Beck

2019

Galaxies

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Energy equipartition between cosmic rays and magnetic fields is often assumed to infer magnetic field properties from the synchrotron observations of star-forming galaxies. However, there is no compelling physical reason to expect the same. We aim to explore the validity of the energy equipartition assumption. After describing popular arguments in favour of the assumption, we first discuss observational results that support it at large scales and how certain observations show significant deviations from equipartition at scales smaller than ≈ 1 kpc , probably related to the propagation length of the cosmic rays. Then, we test the energy equipartition assumption using test-particle and magnetohydrodynamic (MHD) simulations. From the results of the simulations, we find that the energy equipartition assumption is not valid at scales smaller than the driving scale of the ISM turbulence (≈ 100 pc in spiral galaxies), which can be regarded as the lower limit for the scale beyond which equipartition is valid. We suggest that one must be aware of the dynamical scales in the system before assuming energy equipartition to extract magnetic field information from synchrotron observations. Finally, we present ideas for future observations and simulations to investigate in more detail under which conditions the equipartition assumption is valid or not.

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Relative distribution of cosmic rays and magnetic fields

Cited by 41 publications

References 56 publications

Saturation mechanism of the fluctuation dynamo at PrM ≥ 1

Saturation mechanism of the fluctuation dynamo at PrM ≥ 1

IMAGINE: a comprehensive view of the interstellar medium, Galactic magnetic fields and cosmic rays

Revisiting the Equipartition Assumption in Star-Forming Galaxies

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