2008
DOI: 10.1038/nature07477
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An excess of cosmic ray electrons at energies of 300–800 GeV

Abstract: Galactic cosmic rays consist of protons, electrons and ions, most of which are believed to be accelerated to relativistic speeds in supernova remnants. All components of the cosmic rays show an intensity that decreases as a power law with increasing energy (for example as E(-2.7)). Electrons in particular lose energy rapidly through synchrotron and inverse Compton processes, resulting in a relatively short lifetime (about 10(5) years) and a rapidly falling intensity, which raises the possibility of seeing the … Show more

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Cited by 966 publications
(947 citation statements)
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References 27 publications
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“…Electrons produced in local SNRs are expected to fill out the electron spectrum above 100 GeV. In this picture the fraction of positrons in the cosmic ray lepton spectrum should decrease with increasing energy, in contradiction to results from ATIC [6] [4], which show that the positron fraction in fact increases with energy. While this effect could be produced by WIMP dark matter annihilation, the anomalous positron fraction can also be explained by nearby astrophysical sources, most notably pulsars and PWNe.…”
Section: Pulsar Wind Nebulae and The Positron Excesscontrasting
confidence: 42%
See 1 more Smart Citation
“…Electrons produced in local SNRs are expected to fill out the electron spectrum above 100 GeV. In this picture the fraction of positrons in the cosmic ray lepton spectrum should decrease with increasing energy, in contradiction to results from ATIC [6] [4], which show that the positron fraction in fact increases with energy. While this effect could be produced by WIMP dark matter annihilation, the anomalous positron fraction can also be explained by nearby astrophysical sources, most notably pulsars and PWNe.…”
Section: Pulsar Wind Nebulae and The Positron Excesscontrasting
confidence: 42%
“…The Fermi Gamma-ray Space Telescope (Fermi LAT) can map the entire gamma-ray sky between 300 MeV and 500 GeV over all spatial scales, with an angular resolution that ranges from 0.1 • to 1 • depending Figure 1: Comparison to extant data from AMS-02 [4], Fermi LAT [5], ATIC [6], HEAT [7], CAPRICE [8], BETS [9], and H.E.S.S. [10] of a model considering contributions to the e ± flux from the following categories: e − from distant (> 3 kpc) SNRs (dot-dashed yellow) and local SNRs (dotted green), secondary e ± (long dashed red) and e ± from PWNe (short dashed blue).…”
Section: Dramatis Personaementioning
confidence: 99%
“…One way to detect WIMPs is to search for its annihilation/decay products, which may lead to characteristic features in the observed spectra of cosmic electrons (plus positron) or gamma-ray spectra. Some circumstantial evidence or hints of anomalies have been reported [2,3,4]; however, astrophysical sources like pulsars and pulsar wind nebulae can also contribute to these results. Future more precise measurements at higher energies are still needed.…”
Section: Introductionmentioning
confidence: 99%
“…Recently, observations of the cosmic ray (CR) positron fraction by the PAMELA experiment [1], the total electron and positron spectra by the ATIC [2] experiment, the PPB-BETS [3] experiment, the HESS [4,5] experiment and the Fermi [6] experiment all show interesting excesses when compared with the expectations of the conventional astrophysical background.…”
Section: Introductionmentioning
confidence: 99%