Global diffusion of cosmic rays in random magnetic fields

Snodin, A. P.; Shukurov, Anvar; Sarson, Graeme R.; Bushby, P. J.; Rodrigues, Luiz Felippe S.

doi:10.1093/mnras/stw217

Cited by 64 publications

(65 citation statements)

References 62 publications

(97 reference statements)

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“…As discussed above, this high energy scaling is obtained irrespective of the power spectrum, provided most power is concentrated on scales around ∼ l c . These results confirm previous functional forms proposed by Aloisio & Berezinsky (2004) and Parizot (2004) and the numerical results of Casse et al (2002), De Marco et al (2007) and Snodin et al (2016). Observations of isotopic composition (Obermeier et al 2012;Aguilar et al 2016) also support a scaling of…”

Section: Comparison With Numerical Simulationsupporting

confidence: 88%

Charged Particle Diffusion in Isotropic Random Magnetic Fields

Subedi

Sonsrettee²,

Blasi

et al. 2017

ApJ

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The investigation of the diffusive transport of charged particles in a turbulent magnetic field remains a subject of considerable interest. Research has most frequently concentrated on determining the diffusion coefficient in the presence of a mean magnetic field. Here we consider diffusion of charged particles in fully three-dimensional isotropic turbulent magnetic fields with no mean field, which may be pertinent to many astrophysical situations. We identify different ranges of particle energy depending upon the ratio of the Larmor radius of the charged particle to the characteristic outer length scale of the turbulence. Two different theoretical models are proposed to calculate the diffusion coefficient, each applicable to a distinct range of particle energies. The theoretical results are compared with those from computer simulations, showing good agreement.

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Section: Comparison With Numerical Simulationsupporting

confidence: 88%

Charged Particle Diffusion in Isotropic Random Magnetic Fields

Subedi

Sonsrettee²,

Blasi

et al. 2017

ApJ

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“…Decreasing η, the difference between D and D ⊥ increases, while keeping the order D > D ∞ > D ⊥ intact, where D ∞ (E) denotes the diffusion coefficient for pure isotropic turbulence. We note, as previously pointed out by [7,22], that the slope of D ⊥ is larger than 1/3-it is close to 1/2. Assessing whether this slope continues down to GeV energies or not is difficult due to the limited energy range one can probe.…”

Section: Isotropic Turbulence With a Uniform Regular Fieldsupporting

confidence: 88%

Reconciling cosmic ray diffusion with Galactic magnetic field models

Giacinti

Kachelrieß

Semikoz

2018

J. Cosmol. Astropart. Phys.

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We calculate the diffusion coefficients of charged cosmic rays (CR) propagating in regular and turbulent magnetic fields. If the magnetic field is dominated by an isotropic turbulent component, we find that CRs reside too long in the Galactic disc. As a result, CRs overproduce secondary nuclei like boron for any reasonable values of the strength and the coherence length of an isotropic turbulent field. We conclude therefore that the propagation of Galactic CRs has to be strongly anisotropic because of a sufficiently strong regular field and/or of an anisotropy in the turbulent field. As a consequence, the number of sources contributing to the local CR flux is reduced by a factor O(100) compared to the case of isotropic CR diffusion.

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“…the regular field) diffusion coefficient with energy, hinted to by a low-energy extrapolation of numerical simulations. 209,210 Given these considerations, the authors developed a CR transport model based on anisotropic CR transport. The hardening, according to this interpretation, is caused by the progressive transition from perpendicular to parallel vertical escape from the Galactic plane: If confirmed, such a scenario would imply that the hard CR spectrum in the inner Galaxy extends all the way up to the multi-TeV domain, with relevant consequences on the interpretation of How large is the gradient in the spatial distribution of CRs in the Galaxy?…”

Section: Progressive Hardening In the Hadronic Gamma-ray Emissionmentioning

confidence: 99%

The origin of Galactic cosmic rays: Challenges to the standard paradigm

Gabici

Evoli

Gaggero

et al. 2019

Int. J. Mod. Phys. D

163

133

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A critical review of the standard paradigm for the origin of Galactic cosmic rays is presented. Recent measurements of local and far-away cosmic rays reveal unexpected behaviours, which challenge the commonly accepted scenario. These recent findings are discussed, together with long-standing open issues. Despite the progress made thanks to ever-improving observational techniques and theoretical investigations, at present our understanding of the origin and of the behaviour of cosmic rays remains incomplete. We believe it is still unclear whether a modification of the standard paradigm, or rather a radical change of the paradigm itself is needed in order to interpret all the available data 1 arXiv:1903.11584v2 [astro-ph.HE]

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Global diffusion of cosmic rays in random magnetic fields

Cited by 64 publications

References 62 publications

Charged Particle Diffusion in Isotropic Random Magnetic Fields

Charged Particle Diffusion in Isotropic Random Magnetic Fields

Reconciling cosmic ray diffusion with Galactic magnetic field models

The origin of Galactic cosmic rays: Challenges to the standard paradigm

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