Literature DB >> 23006255

Spectral breaks as a signature of cosmic ray induced turbulence in the Galaxy.

Pasquale Blasi1, Elena Amato, Pasquale D Serpico.   

Abstract

We show that the complex shape of the cosmic ray (CR) spectrum, as recently measured by PAMELA and inferred from Fermi-LAT γ-ray observations of molecular clouds in the Gould belt, can be naturally understood in terms of basic plasma astrophysics phenomena. A break from a harder to a softer spectrum at rigidity R is approximately equal to 10 GV follows from a transition from transport dominated by advection of particles with Alfvén waves to a regime where diffusion in the turbulence generated by the same CRs is dominant. A second break at R is approximately equal to 200 GV happens when the diffusive propagation is no longer determined by the self-generated turbulence, but rather by the cascading of externally generated turbulence (for instance due to supernova bubbles) from large spatial scales to smaller scales where CRs can resonate. Implications of this scenario for the cosmic ray spectrum, grammage, and anisotropy are discussed.

Entities:  

Year:  2012        PMID: 23006255     DOI: 10.1103/PhysRevLett.109.061101

Source DB:  PubMed          Journal:  Phys Rev Lett        ISSN: 0031-9007            Impact factor:   9.161


  2 in total

1.  The basis for cosmic ray feedback: Written on the wind.

Authors:  Ellen G Zweibel
Journal:  Phys Plasmas       Date:  2017-05-24       Impact factor: 2.023

2.  Measurement of the cosmic ray proton spectrum from 40 GeV to 100 TeV with the DAMPE satellite.

Authors:  Q An; R Asfandiyarov; P Azzarello; P Bernardini; X J Bi; M S Cai; J Chang; D Y Chen; H F Chen; J L Chen; W Chen; M Y Cui; T S Cui; H T Dai; A D'Amone; A De Benedittis; I De Mitri; M Di Santo; M Ding; T K Dong; Y F Dong; Z X Dong; G Donvito; D Droz; J L Duan; K K Duan; D D'Urso; R R Fan; Y Z Fan; F Fang; C Q Feng; L Feng; P Fusco; V Gallo; F J Gan; M Gao; F Gargano; K Gong; Y Z Gong; D Y Guo; J H Guo; X L Guo; S X Han; Y M Hu; G S Huang; X Y Huang; Y Y Huang; M Ionica; W Jiang; X Jin; J Kong; S J Lei; S Li; W L Li; X Li; X Q Li; Y Li; Y F Liang; Y M Liang; N H Liao; C M Liu; H Liu; J Liu; S B Liu; W Q Liu; Y Liu; F Loparco; C N Luo; M Ma; P X Ma; S Y Ma; T Ma; X Y Ma; G Marsella; M N Mazziotta; D Mo; X Y Niu; X Pan; W X Peng; X Y Peng; R Qiao; J N Rao; M M Salinas; G Z Shang; W H Shen; Z Q Shen; Z T Shen; J X Song; H Su; M Su; Z Y Sun; A Surdo; X J Teng; A Tykhonov; S Vitillo; C Wang; H Wang; H Y Wang; J Z Wang; L G Wang; Q Wang; S Wang; X H Wang; X L Wang; Y F Wang; Y P Wang; Y Z Wang; Z M Wang; D M Wei; J J Wei; Y F Wei; S C Wen; D Wu; J Wu; L B Wu; S S Wu; X Wu; K Xi; Z Q Xia; H T Xu; Z H Xu; Z L Xu; Z Z Xu; G F Xue; H B Yang; P Yang; Y Q Yang; Z L Yang; H J Yao; Y H Yu; Q Yuan; C Yue; J J Zang; F Zhang; J Y Zhang; J Z Zhang; P F Zhang; S X Zhang; W Z Zhang; Y Zhang; Y J Zhang; Y L Zhang; Y P Zhang; Y Q Zhang; Z Zhang; Z Y Zhang; H Zhao; H Y Zhao; X F Zhao; C Y Zhou; Y Zhou; X Zhu; Y Zhu; S Zimmer
Journal:  Sci Adv       Date:  2019-09-27       Impact factor: 14.136
  2 in total

北京卡尤迪生物科技股份有限公司 © 2022-2023.