Spatial-Dependent Propagation of Cosmic Rays Results in Spectrum of Proton, Ratios of 
   , B/C and Anisotropy of Nuclei

Guo, Yi-Qing; Tian, Zhen; Jin, Chao

doi:10.3847/0004-637x/819/1/54

Cited by 86 publications

(110 citation statements)

References 76 publications

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“…Second, we assume a relatively simple propagation paradigm with a uniform diffusion coefficient. However, the actual case might be more complicated, as indicated by precise measurements of the CR spectra and diffuse γ-rays [32,53,54]. The impact of these alternative propagation configurations on the antiproton calculation deserves further detailed investigation.…”

Section: Conclusion and Discussionmentioning

confidence: 99%

Revisit of cosmic ray antiprotons from dark matter annihilation with updated constraints on the background model from AMS-02 and collider data

Cui

Yuan

et al. 2018

J. Cosmol. Astropart. Phys.

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We study the cosmic ray antiprotons with updated constraints on the propagation, proton injection, and solar modulation parameters based on the newest AMS-02 data near the Earth and Voyager data in the local interstellar space, and on the cross section of antiproton production due to proton-proton collisions based on new collider data. We use a Bayesian approach to properly consider the uncertainties of the model predictions of both the background and the dark matter (DM) annihilation components of antiprotons. We find that including an extra component of antiprotons from the annihilation of DM particles into a pair of quarks can improve the fit to the AMS-02 antiproton data considerably. The favored mass of DM particles is about 60 ∼ 100 GeV, and the annihilation cross section is just at the level of the thermal production of DM ( σv ∼ O(10 −26 ) cm 3 s −1 ).

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Section: Conclusion and Discussionmentioning

confidence: 99%

Revisit of cosmic ray antiprotons from dark matter annihilation with updated constraints on the background model from AMS-02 and collider data

Cui

Yuan

et al. 2018

J. Cosmol. Astropart. Phys.

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“…The diffusion coefficient may vary in the Milky Way due to different magnetic field distributions in the disk and halo (e.g., [45,46]). In particular, CRs may be confined much longer around the sources than expected due to non-linear self-generation of MHD waves via streaming instability [47].…”

Section: Propagation Modelsmentioning

confidence: 99%

Propagation of cosmic rays in the AMS-02 era

et al. 2017

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In this work we use the newly reported Boron-to-Carbon ratio (B/C) from AMS-02 and the time-dependent proton fluxes from PAMELA and AMS-02 to constrain the source and propagation parameters of cosmic rays in the Milky Way. A linear correlation of the solar modulation parameter with solar activities is assumed to account for the time-varying cosmic ray fluxes. A comprehensive set of propagation models, with/without reacceleration or convection, have been discussed and compared. We find that only the models with reacceleration can selfconsistently fit both the proton and B/C data. The rigidity dependence slope of the diffusion coefficient, δ, is found to be about 0.38 − 0.50 for the diffusion-reacceleration models. The plain diffusion and diffusionconvection models fit the data poorly. We compare different model predictions of the positron and antiproton fluxes with the data. We find that the diffusion-reacceleration models over-produce low energy positrons, while non-reacceleration models give better fit to the data. As for antiprotons, reacceleration models tend to underpredict low energy antiproton fluxes, unless a phenomenological modification of the velocity-dependence of the diffusion coefficient is applied. Our results suggest that there could be important differences of the propagation for nuclei and leptons, in either the Milky Way or the solar heliosphere.PACS numbers: 95.35.+d,96.50.S-

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“…However, remarkable spectral hardenings at an rigidity of a few hundred GV on the spectra of all major nuclei components were reported by the balloon-borne experiments ATIC-2 [25] and CREAM [26], and were confirmed with higher precision by the space detectors PAMELA [27] and AMS-02 [28,29]. Many kinds of models have been proposed to understand the origin of the spectral hardenings, including the super-position of different sources [30][31][32], the non-linear acceleration of the supernova remnant shocks [33,34], the re-acceleration mechanism when particles propagating in the Galaxy [35], and the spatially-dependent diffusion of CRs [36][37][38][39][40][41][42].…”

Section: Introductionmentioning

confidence: 94%

“…One possible physical explanation of the spectral hardening (β · log E) is the spatially-dependent diffusion of particles [36,39,41,42,50]. In a simplified version, i.e., CRs diffuse separately in the disk region and halo region (the two-halo model), the hardening of the primary CR nuclei and the excesses of secondary particles can be reasonably accounted for [36,41,42,50]. Here we extrapolate this model to the knee region to reproduce the results of the phenomenological "modified poly-gonato" model.…”

Section: The Spatially-dependent Diffusion Modelmentioning

confidence: 99%

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On the knee of Galactic cosmic rays in light of sub-TeV spectral hardenings

Guo

Yuan

2018

Chinese Phys. C

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More than fifty years after the discovery of the knee in the cosmic ray (CR) spectra, its physical origin remains a mystery. This is partly due to the ambiguity of the energy spectrum of individual composition. Recently, direct measurements from several space experiments found significant spectral hardenings of CR nuclei at ∼ 200 GV. A joint modeling of the direct and indirect measurements may help to understand the experimental systematics and probably the physics of the knee. In this work, we update the phenomenological "poly-gonato" model to include the spectral hardenings, with a changing spectral index of γ+β·log E. This modification gives a reasonable description to the CR spectra in a wide energy range. However, the fits to different data sets result in somehow different results. We find that the fit to the AMS-02 and CREAM data slightly favors a relatively low energy knee of the light components. In such a case, the expected all-particle spectra under-shoot the data, which may require an extra component of CRs. The fits to AMS-02 data and the light component (H+He) data from Tibet ASγ/ARGO-YBJ/WFCTA or KASCADE experiments give consistent results with the all-particle spectra. We further propose a possible physical realization of such a "modified poly-gonato" model of spectral hardenings by means of spatially-dependent diffusion of CRs. We find reasonably good agreement between the model predictions and the data about CR spectra, the secondary-to-primary ratios, and the amplitude of anisotropies.

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Spatial-Dependent Propagation of Cosmic Rays Results in Spectrum of Proton, Ratios of , B/C and Anisotropy of Nuclei

Abstract: Recent precise measurements of cosmic ray spectra revealed an anomalous hardening at ∼200 GV, observed by the ATIC, CREAM, PAMELA, and AMS02 experiments. Particularly, the latest observation of the Show more

Cited by 86 publications

References 76 publications

Revisit of cosmic ray antiprotons from dark matter annihilation with updated constraints on the background model from AMS-02 and collider data

Revisit of cosmic ray antiprotons from dark matter annihilation with updated constraints on the background model from AMS-02 and collider data

Propagation of cosmic rays in the AMS-02 era

On the knee of Galactic cosmic rays in light of sub-TeV spectral hardenings

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