Stochastic cosmic ray sources and the TeV break in the all-electron spectrum

Mertsch, Philipp

doi:10.1088/1475-7516/2018/11/045

Cited by 39 publications

(30 citation statements)

References 83 publications

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“…at TeV energies and beyond, stochasticity effects due to the discrete nature of the SNRs will shape the electron spectrum (e.g. [6]). As we were mainly concerned with lower energies, we have considered a smooth distribution of sources, which produces the expectation value of the flux at any one energy.…”

Section: Discussionmentioning

confidence: 99%

Breaks in interstellar spectra of positrons and electrons derived from time-dependent AMS data

et al. 2019

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Until fairly recently, it was widely accepted that local cosmic ray spectra were largely featureless power laws, containing limited information on their acceleration and transport. This viewpoint is currently being revised in the light of evidence for a variety of spectral breaks in the fluxes of cosmic ray nuclei. Here, we focus on cosmic ray electrons and positrons which at the highest energies must be of local origin due to strong radiative losses. We consider a pure diffusion model for their Galactic transport and determine its free parameters by fitting data in a wide energy range: measurements of the interstellar spectrum by Voyager at MeV energies, radio synchrotron data (sensitive to GeV electrons and positrons) and local observations by AMS up to ∼ 1 TeV. For the first time, we also model the time-dependent fluxes of cosmic ray electrons and positrons at GeV energies recently presented by AMS, treating solar modulation in a simple extension of the widely used force-field approximation. We are able to reproduce all the available measurements to date. Our model of the interstellar spectrum of cosmic ray electrons and positrons requires the presence of a number of spectral breaks, both in the source spectra and the diffusion coefficients. While we remain agnostic as to the origin of these spectral breaks, their presence will inform future models of the microphysics of cosmic ray acceleration and transport. arXiv:1904.05899v1 [astro-ph.HE]

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Section: Discussionmentioning

confidence: 99%

Breaks in interstellar spectra of positrons and electrons derived from time-dependent AMS data

et al. 2019

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“…Ref. [28]). A large number of supernova remnants contribute to the cosmicray spectrum, with a variety of ages and at a range of distances from the Solar System.…”

Section: A Cosmic-ray Injection and Propagation In The Interstellar mentioning

confidence: 99%

A robust excess in the cosmic-ray antiproton spectrum: Implications for annihilating dark matter

2019

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An excess of ∼10-20 GeV cosmic-ray antiprotons has been identified in the spectrum reported by the AMS-02 Collaboration. The systematic uncertainties associated with this signal, however, have made it difficult to interpret these results. In this paper, we revisit the uncertainties associated with the time, charge and energy-dependent effects of solar modulation, the antiproton production cross section, and interstellar cosmic-ray propagation. After accounting for these uncertainties, we confirm the presence of a 4.7σ antiproton excess, consistent with that arising from a mχ ≈ 64 − 88 GeV dark matter particle annihilating to bb with a cross section of σv (0.8 − 5.2) × 10 −26 cm 3 /s. If we allow for the stochastic acceleration of secondary antiprotons in supernova remnants, the data continues to favor a similar range of dark matter models (mχ ≈ 46−94 GeV, σv ≈ (0.7−3.8)×10 −26 cm 3 /s) with a significance of 3.3σ. The same range of dark matter models that are favored to explain the antiproton excess can also accommodate the excess of GeV-scale gamma rays observed from the Galactic Center.

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“…The large statistical uncertainties above the TeV region and the observed discrepancies below the TeV region add further complexities in the data interpretation of the origin of the spectral break and of the tentative feature observed at 1.4 TeV by DAMPE, which could be explained involving new astrophysical mechanisms or DM related effects [64,[107][108][109][110][111][112][113][114]. Redundant measurements of the (e + +e − ) energies and spectra are a fundamental requirement to reduce systematic uncertainties.…”

Section: High Energy Crs (Electrons Protons and Nuclei)mentioning

confidence: 99%

High precision particle astrophysics as a new window on the universe with an Antimatter Large Acceptance Detector In Orbit (ALADInO)

et al. 2021

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Multimessenger astrophysics is based on the detection, with the highest possible accuracy, of the cosmic radiation. During the last 20 years, the advent space-borne magnetic spectrometers in space (AMS-01, Pamela, AMS-02), able to measure the charged cosmic radiation separating matter from antimatter, and to provide accurate measurement of the rarest components of Cosmic Rays (CRs) to the highest possible energies, have become possible, together with the ultra-precise measurement of ordinary CRs. These developments started the era of precision Cosmic Ray physics providing access to a rich program of high-energy astrophysics addressing fundamental questions like matter-antimatter asymmetry, indirect detection for Dark Matter and the detailed study of origin, acceleration and propagation of CRs and their interactions with the interstellar medium.In this paper we address the above-mentioned scientific questions, in the context of a second generation, large acceptance, superconducting magnetic spectrometer proposed as mission in the context of the European Space Agency’s Voyage2050 long-term plan: the Antimatter Large Acceptance Detector In Orbit (ALADInO) would extend by about two orders of magnitude in energy and flux sensitivity the separation between charged particles/anti-particles, making it uniquely suited for addressing and potentially solving some of the most puzzling issues of modern cosmology.

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Stochastic cosmic ray sources and the TeV break in the all-electron spectrum

Cited by 39 publications

References 83 publications

Breaks in interstellar spectra of positrons and electrons derived from time-dependent AMS data

Breaks in interstellar spectra of positrons and electrons derived from time-dependent AMS data

A robust excess in the cosmic-ray antiproton spectrum: Implications for annihilating dark matter

High precision particle astrophysics as a new window on the universe with an Antimatter Large Acceptance Detector In Orbit (ALADInO)

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