253 research outputs found

    Are extragalactic gamma ray bursts the source of the highest energy cosmic rays?

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    Recent observations with the large air shower arrays of ultra high energy cosmic rays (UHECR) and recent measurements/estimates of the redshifts of gamma ray bursts (GRBs) seem to rule out extragalactic GRBs as the source of the cosmic rays that are observed near Earth, including those with the highest energies.Comment: ApJL, submitte

    Dark Matter and Big Bang Nucleosynthesis

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    The recently observed Deuterium abundance in a low- metallicity high-redshift hydrogen cloud, which is about ten times larger than that observed in the near interstellar medium, is that expected from the Standard Big Bang Nucleosynthesis theory and the observed abundances of 4^4He and 7^7Li extrapolated to their primordial values. The inferred cosmic baryon to photon ratio, η=(1.60±0.1)×10−10,\eta=(1.60\pm 0.1)\times 10^{-10}, yields a mean cosmic baryon density, in critical mass units, of Ωb≈(0.6±0.1)×10−2h−2,\Omega_b\approx (0.6\pm 0.1)\times 10^{-2}h^{-2}, with hh being the Hubble constant in units of 100km s−1Mpc−1100 km~s^{-1} Mpc^{-1}. This baryon density is consistent with the mean cosmic density of matter visible optically and in X-rays. It implies that most of the baryons in the Universe are visible and are not dark. Combined with the observed ratio of baryons to light in X-ray emitting clusters, it yields the value Ω≈0.15\Omega \approx 0.15 for the mean mass density of the Universe, which is consistent with that obtained from the mass to light ratio in clusters. This mass density is about ten times larger than the mean baryon mass density. It indicates that most of the matter in the Universe consists of nonbaryonic dark matter.Comment: Invited talk to be published in the proceedings of ``Dark Matter In Cosmology'' (Villars sur Ollon, Switzerland January 21-28, 1995
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