* Astronomy

Title: Is the PAMELA anomaly caused by the supernova explosions near the Earth?
Authors: Yutaka Fujita (Osaka), Kazunori Kohri (Lancaster), Ryo Yamazaki (Hiroshima), Kunihito Ioka (KEK)
(Version v3)

We show that the anomaly of the positron fraction observed by the PAMELA experiment can be attributed to recent supernova explosion(s) in a dense gas cloud (DC) near the Earth. Protons are accelerated around the supernova remnant (SNR). Electrons and positrons are created through hadronic interactions inside the DC. Their spectrum is harder than that of the background because the SNR spends much time in a radiative phase. Our scenario predicts that the anti-proton flux dominates that of the background for >~100 GeV. We compare the results with observations (Fermi, HESS, PPB-BETS, and ATIC).

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Excess positrons are linked to Geminga pulsar
Are recently-detected excesses of cosmic electrons and positrons the first direct evidence for the existence of dark matter particles? That has been the hope of many physicists, while others have suggested a more mundane origin in a nearby pulsar. Now researchers in the US claim that the excesses can be linked to high-energy gamma rays emitted by the Geminga pulsar.
Cold dark matter is the most accepted explanation as to why the universe appears to have at least 80% more gravitating mass than is directly visible. Dark-matter particles are expected to collide with one another and annihilate - producing high energy particles such as electrons and positrons. If these particles could be observed, they would represent the most direct evidence yet for the existence of dark matter.

Source

Title: Explaining PAMELA and WMAP data through Coannihilations in Extended SUGRA with Collider Implications
Authors: Daniel Feldman, Zuowei Liu, Pran Nath, Brent D. Nelson

The PAMELA positron excess is analysed within the framework of nonuniversal SUGRA models with an extended U(1)^n gauge symmetry in the hidden sector leading to neutralino dark matter with either a mixed Higgsino-wino LSP or an essentially pure wino dominated LSP. The Higgsino-wino LSP can produce the observed PAMELA positron excess and satisfy relic density constraints in the extended class of models due to a near degeneracy of the mass spectrum of the extended neutralino sector with the LSP mass. The simultaneous satisfaction of the WMAP relic density data and the PAMELA data is accomplished through a co-annihilation mechanism (B_{Co}-mechanism), and leads to predictions of a neutralino and a chargino in the mass range (180-200) GeV as well as low lying sparticles accessible at colliders. We show that the models are consistent with the antiproton constraints from PAMELA as well as photon flux data from EGRET and FERMI-LAT. Predictions for the scalar neutralino proton cross section relevant for the direct detection of dark matter are also discussed and signatures at the LHC for these PAMELA inspired models are analysed. It is shown that the mixed Higgsino-wino LSP model will be discoverable with as little as 1 fb^{-1} of data and is thus a prime candidate for discovery in the low luminosity runs at the LHC.

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Title: Extragalactic Inverse Compton Light from Dark Matter Annihilation and the Pamela Positron Excess
Authors: Stefano Profumo, Tesla E. Jeltema

We calculate the extragalactic diffuse emission originating from the up-scattering of cosmic microwave photons by energetic electrons and positrons produced in particle dark matter annihilation events at all redshifts and in all halos. We outline the observational constraints on this emission and we study its dependence on both the particle dark matter model (including the particle mass and its dominant annihilation final state) and on assumptions on structure formation and on the density profile of halos. We find that for low-mass dark matter models, data in the X-ray band provide the most stringent constraints, while the gamma-ray energy range probes models featuring large masses and pair-annihilation rates, and a hard spectrum for the injected electrons and positrons. Specifically, we point out that the all-redshift, all-halo inverse Compton emission from many dark matter models that might provide an explanation to the anomalous positron fraction measured by the Pamela payload severely overproduces the observed extragalactic gamma-ray background.

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