Bridget Bertoni scite author profile

Dark matter annihilations taking place in nearby subhalos could appear as gamma-ray sources without detectable counterparts at other wavelengths. In this study, we consider the collection of unassociated gamma-ray sources reported by the Fermi Collaboration in an effort to identify the most promising dark matter subhalo candidates. While we identify 24 bright, high-latitude, non-variable sources with spectra that are consistent with being generated by the annihilations of ∼ 20-70 GeV dark matter particles (assuming annihilations to bb), it is not possible at this time to distinguish these sources from radio-faint gamma-ray pulsars. Deeper multi-wavelength observations will be essential to clarify the nature of these sources. It is notable that we do not find any such sources that are well fit by dark matter particles heavier than ∼100 GeV. We also study the angular distribution of the gamma-rays from this set of subhalo candidates, and find that the source 3FGL J2212.5+0703 prefers a spatially extended profile (of width ∼ 0.15 • ) over that of a point source, with a significance of 4.2σ (3.6σ after trials factor).Although not yet definitive, this bright and high-latitude gammaray source is well fit as a nearby subhalo of mχ 20-50 GeV dark matter particles (annihilating to bb) and merits further multi-wavelength investigation. Based on the subhalo distribution predicted by numerical simulations, we derive constraints on the dark matter annihilation cross section that are competitive to those resulting from gamma-ray observations of dwarf spheroidal galaxies, the Galactic Center, and the extragalactic gamma-ray background. PACS numbers: 95.35.+d, 95.95.Pw, 07.85.-m, FERMILAB-PUB-15-124-A arXiv:1504.02087v1 [astro-ph.HE] 8 Apr 2015

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Dark matter thermalization in neutron stars

Bertoni

2013

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We study how many-body effects alter the dark matter (DM) thermalization time inside neutron stars. We find that Pauli blocking, kinematic constraints, and superfluidity and superconductivity in the neutron star significantly affect the DM thermalization time, in general lengthening it. This could change the final DM mass and DM-nucleon cross section constraints by considering black hole formation in neutron stars due to DM accretion. We consider the class of models in which DM is an asymmetric, complex scalar particle with a mass between 1 keV and 5 GeV which couples to regular matter via some heavy vector boson. Interestingly, we find that the discovery of asymmetric, bosonic DM could motivate the existence of exotic neutron star cores. We apply our results to the case of mixed sneutrino DM. PACS numbers: 95.35.+d, 95.30.Cq, 97.60.Jd

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Constraints and consequences of reducing small scale structure via large dark matter-neutrino interactions

Bertoni

Ipek

McKeen

et al. 2015

J. High Energ. Phys.

106

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Cold dark matter explains a wide range of data on cosmological scales. However, there has been a steady accumulation of evidence for discrepancies between simulations and observations at scales smaller than galaxy clusters. One promising way to affect structure formation on small scales is a relatively strong coupling of dark matter to neutrinos. We construct an experimentally viable, simple, renormalizable model with new interactions between neutrinos and dark matter and provide the first discussion of how these new dark matter-neutrino interactions affect neutrino phenomenology. We show that addressing the small scale structure problems requires asymmetric dark matter with a mass that is tens of MeV. Generating a sufficiently large dark matter-neutrino coupling requires a new heavy neutrino with a mass around 100 MeV. The heavy neutrino is mostly sterile but has a substantial τ neutrino component, while the three nearly massless neutrinos are partly sterile. This model can be tested by future astrophysical, particle physics, and neutrino oscillation data. Promising signatures of this model include alterations to the neutrino energy spectrum and flavor content observed from a future nearby supernova, anomalous matter effects in neutrino oscillations, and a component of the τ neutrino with mass around 100 MeV.

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Is the gamma-ray source 3FGL J2212.5+0703 a dark matter subhalo?

Bertoni

Hooper

Linden

2016

J. Cosmol. Astropart. Phys.

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Abstract. In a previous paper, we pointed out that the gamma-ray source 3FGL J2212.5+0703shows evidence of being spatially extended. If a gamma-ray source without detectable emission at other wavelengths were unambiguously determined to be spatially extended, it could not be explained by known astrophysics, and would constitute a smoking gun for dark matter particles annihilating in a nearby subhalo. With this prospect in mind, we scrutinize the gamma-ray emission from this source, finding that it prefers a spatially extended profile over that of a single point-like source with 5.1σ statistical significance. We also use a large sample of active galactic nuclei and other known gamma-rays sources as a control group, confirming, as expected, that statistically significant extension is rare among such objects. We argue that the most likely (non-dark matter) explanation for this apparent extension is a pair of bright gamma-ray sources that serendipitously lie very close to each other, and estimate that there is a chance probability of ∼2% that such a pair would exist somewhere on the sky. In the case of 3FGL J2212.5+0703, a model with a second gamma-ray point source at the location of a known BZCAT/CRATES radio source yields fits that are comparable in quality to those obtained for a single extended source. If 3FGL J2212.5+0703 is a dark matter subhalo, it would imply that dark matter particles have a mass of ∼18-33 GeV and an annihilation cross section on the order of σv ∼ 10 −26 cm 3 /s (for the representative case of annihilations to bb), similar to the values required to generate the Galactic Center gamma-ray excess.arXiv:1602.07303v1 [astro-ph.HE]

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Bridget Bertoni

Examining The Fermi-LAT Third Source Catalog in search of dark matter subhalos

Dark matter thermalization in neutron stars

Constraints and consequences of reducing small scale structure via large dark matter-neutrino interactions

Is the gamma-ray source 3FGL J2212.5+0703 a dark matter subhalo?

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