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2 results

  • 16 - Location and Geometry of Emitters

  • from Part III - Neutron Star Physics
  • Andrew Lyne, University of Manchester, Francis Graham-Smith, University of Manchester, Benjamin Stappers, University of Manchester
  • Book:
    Pulsar Astronomy
    Published online:
    21 July 2022
    Print publication:
    04 August 2022, pp 258-279

  • Summary

    The radio and high-energy profiles show that the emitting regions are concentrated in gaps in the magnetosphere located over the magnetic poles and near the velocity of light cylinder. The radio sources of most normal pulsars are distributed unevenly over the polar cap and are highly concentrated, broadband and variable. Their excitation may move laterally, causing drifting in sub-pulse timing. Other radio emitters are located close to the gamma-ray emitters in the outer magnetosphere. Almost all radio pulses are highly polarised; the sweep of position angle in the radio pulses is related to the magnetic field at the location of the emitters.

  • Search for High Energy emission from GRBs with MAGIC

  • Alessio Berti, for the MAGIC GRB group
  • Journal:
    Proceedings of the International Astronomical Union / Volume 12 / Issue S324 / September 2016
    Published online by Cambridge University Press:
    23 June 2017, pp. 70-73
    Print publication:
    September 2016
    • Article
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  • Gamma-Ray Bursts (GRBs) are the most violent explosions in the Universe, releasing a huge amount of energy in few seconds. While our understanding of the prompt and the afterglow phases has increased with Swift and Fermi, we have very few information about their High Energy (HE, E ≲ 100) emission components. This requires a ground-based experiment able to perform fast follow-up with enough sensitivity above ~ 50 GeV. The MAGIC (Major Atmospheric Gamma-ray Imaging Cherenkov) telescopes have been designed to perform fast follow-up on GRBs thanks to fast slewing movement and low energy threshold (~ 50 GeV). Since the beginning of the operations, MAGIC followed-up 89 GRBs in good observational conditions. In this contribution the MAGIC GRBs follow-up campaign and the results which could be obtained by detecting HE and Very High Energy (VHE, E ≳ 100 GeV) γ-rays from GRBs will be reviewed.