Both diffuse high-energy gamma rays and an extended electron-positron annihilation line emission have been observed in the Galactic Center (GC) region. Although X-ray observations indicate that the Galactic black hole Sgr A Ã is inactive now, we suggest that Sgr A Ã can become active when a captured star is tidally disrupted and matter is accreted into the black hole. As a consequence the Galactic black hole could be a powerful source of relativistic protons. We are able to explain the current observed diffuse gamma rays and the very detailed 511 keV annihilation line of secondary positrons by p-p collisions of such protons, with appropriate injection times and energy. Relativistic protons could have been injected into the ambient material if the black hole captured a 50 M star at several tens times 10 6 yr ago. An alternative possibility is that the black hole continues to capture stars with $1 M every 10 5 yr. Secondary positrons produced by p-p collisions at energies k30 MeV are cooled down to thermal energies by Coulomb collisions and are annihilated in the warm neutral and ionized phases of the interstellar medium with temperatures about several eV, because the annihilation cross section reaches its maximum at these temperatures. It takes about 10 million years for the positrons to cool down to thermal temperatures so that they can diffuse into a very large extended region around the GC. A much more recent star capture may also be able to account for recent TeVobservations within 10 pc of the GC, as well as for the unidentified GeV gamma-ray sources found by EGRET at GC. The spectral difference between the GeV and TeV flux could be explained naturally in this model as well.
Some historical remarks concerning the strange stars are briefly discussed. The recent developments in physics and dynamical behavior of strange stars are reviewed. Especially, various observational effects in distinguishing strange stars from neutron stars and related interesting astrophysical phenomena are also discussed.
Gamma-ray burst remnants become trans-relativistic typically in days to tens
of days, and they enter the deep Newtonian phase in tens of days to months,
during which the majority of shock-accelerated electrons will no longer be
highly relativistic. However, a small portion of electrons are still
accelerated to ultra-relativistic speeds and capable of emitting synchrotron
radiation. The distribution function for electrons is re-derived here so that
synchrotron emission from these relativistic electrons can be calculated. Based
on the revised model, optical afterglows from both isotropic fireballs and
highly collimated jets are studied numerically, and compared to analytical
results. In the beamed cases, it is found that, in addition to the steepening
due to the edge effect and the lateral expansion effect, the light curves are
universally characterized by a flattening during the deep Newtonian phase.Comment: MNRAS in press (originally submitted in October 2002), 8 pages with 8
eps figures embedded, references update
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