AMS-02 fits dark matter

Balázs, Csaba; Li, Tong

doi:10.1007/jhep05(2016)033

Cited by 3 publications

(4 citation statements)

References 118 publications

(146 reference statements)

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“…As mentioned above, for each set of dark matter mass and mediator mass, we first generate the antiproton spectrum dN p/dE, and calculate the dark matter annihilation cross section. These dark matter model dependent variables are then passed into the public code Galprop v54 [43][44][45][46][47] to ensure that near Earth cosmic ray fluxes from dark matter annihilation and background are obtained in a consistent way [48]. The obtained cosmic ray fluxes, together with the experimental data points, are put into a composite likelihood function, defined as…”

Section: Antiproton Flux From Ams-02mentioning

confidence: 99%

Revisiting simplified dark matter models in terms of AMS-02 and Fermi-LAT

2018

J. High Energ. Phys.

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Abstract:We perform an analysis of the simplified dark matter models in the light of cosmic ray observables by AMS-02 and Fermi-LAT. We assume fermion, scalar or vector dark matter particle with a leptophobic spin-0 mediator that couples only to Standard Model quarks and dark matter via scalar and/or pseudo-scalar bilinear. The propagation and injection parameters of cosmic rays are determined by the observed fluxes of nuclei from AMS-02. We find that the AMS-02 observations are consistent with the dark matter framework within the uncertainties. The AMS-02 antiproton data prefer 30 (50) GeV -5 TeV dark matter mass and require an effective annihilation cross section in the region of 4 × 10 −27 (7 × 10 −27 ) -4 × 10 −24 cm 3 /s for the simplified fermion (scalar and vector) dark matter models. The cross sections below 2 × 10 −26 cm 3 /s can evade the constraint from Fermi-LAT dwarf galaxies for about 100 GeV dark matter mass.

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Section: Antiproton Flux From Ams-02mentioning

confidence: 99%

Revisiting simplified dark matter models in terms of AMS-02 and Fermi-LAT

2018

J. High Energ. Phys.

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“…A self-consistent way to take into account the dark matter source is to propagate the antiproton spectrum induced by dark matter annihilation through the Galaxy and calculate the antiproton flux under the exact same set of the above astrophysical parameters. This procedure ensures a consistent astrophysical treatment of cosmic rays from the standard astrophysical source and dark matter [12].…”

Section: Introductionmentioning

confidence: 99%

Simplified dark matter models in the light of AMS-02 antiproton data

Li¹

2017

J. High Energ. Phys.

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In this work we perform an analysis of the recent AMS-02 antiproton flux and the antiproton-to-proton ratio in the framework of simplified dark matter models. To predict the AMS-02 observables we adopt the propagation and injection parameters determined by the observed fluxes of nuclei. We assume that the dark matter particle is a Dirac fermionic dark matter, with leptophobic pseudoscalar or axialvector mediator that couples only to Standard Model quarks and dark matter particles. We find that the AMS-02 observations are consistent with the dark matter framework within the uncertainties. The antiproton data prefer a dark matter (mediator) mass in the 700 GeV-5 TeV region for the annihilation with pseudoscalar mediator and greater than 700 GeV (200 GeV-1 TeV) for the annihilation with axialvector mediator, respectively, at about 68% confidence level. The AMS-02 data require an effective dark matter annihilation cross section in the region of 1 × 10 −25 -1 × 10 −24 (1 × 10 −25 -4 × 10 −24 ) cm 3 /s for the simplified model with pseudoscalar (axialvector) mediator. The constraints from the LHC and Fermi-LAT are also discussed.

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“…In this section, we describe the simplified dark matter model we use in our analysis. Majorana fermions recently emerged as the most plausible dark matter particle candidates in the simplified model context [80,[122][123][124][127][128][129][130][131]. Motivated by this, we assume that dark matter consists of a single Majorana fermion, which we denote by χ. Additionally, motivated by the listed literature and the Higgs portal, we assume that the interaction between the dark matter particle and standard fermions is mediated by a scalar particle S [132,133].…”

Section: The Dark Matter Modelmentioning

confidence: 99%

“…To make minimal and general theoretical assumptions we use the simplified model framework assuming that dark matter is a Majorana fermion coupling to standard fermions via a scalar mediator. This particular simplified model has unsuppressed indirect, and suppressed direct and collider detection rates, and emerged as the most plausible one when compared with a wide range of data [123][124][125]. To show the role of the IEM assumptions in constraining dark matter properties, we infer the properties JCAP02(2017)037 of these dark matter particles using the multiple Fermi data sets categorized by different choices of IEMs and spectral models.…”

Section: Introductionmentioning

confidence: 99%

Dark matter properties implied by gamma ray interstellar emission models

Balázs

2017

J. Cosmol. Astropart. Phys.

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We infer dark matter properties from gamma ray residuals extracted using eight different interstellar emission scenarios proposed by the Fermi-LAT Collaboration to explain the Galactic Center gamma ray excess. Adopting the most plausible simplified ansatz, we assume that the dark matter particle is a Majorana fermion interacting with standard fermions via a scalar mediator. Using this theoretical hypothesis and the Fermi residuals we calculate Bayesian evidences, including Fermi-LAT exclusion limits from 15 dwarf spheroidal galaxies as well. Our Bayes factors single out four of the Fermi scenarios as compatible with the simplified dark matter model. In the most preferred scenario the dark matter (mediator) mass is in the 100-500 (1-200) GeV range and its annihilation is dominated by top quark final state. Less preferred but still plausible is annihilation into bb and τ + τ − final states with an order of magnitude lower dark matter mass.Our conclusion is that the properties of dark matter extracted from gamma ray data are highly sensitive to the modeling of the interstellar emission.

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AMS-02 fits dark matter

Cited by 3 publications

References 118 publications

Revisiting simplified dark matter models in terms of AMS-02 and Fermi-LAT

Revisiting simplified dark matter models in terms of AMS-02 and Fermi-LAT

Simplified dark matter models in the light of AMS-02 antiproton data

Dark matter properties implied by gamma ray interstellar emission models

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