| 1 | \section{Introduction}
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| 2 |
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| 3 | \subsection{Observation of GRBs}
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| 4 |
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| 5 | The \ma telescope's support structure and mirrors have been designed exceptionally light in order to
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| 6 | react quickly to GRB alerts from satellites. \cite{design} and~\cite{PETRY} set
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| 7 | the objective to turn the telescope to the burst position within 10-30\,sec.
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| 8 | in order to have a fair chance to detect a burst when the prompt $\gamma$--emission is still ongoing.
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| 9 | During the commissioning phase it could be proven that our goal was reached.
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| 10 | The telescope is able to turn 180 degrees in azimuth within 20\,sec. and 80 degrees in zenith within 10\,sec.\\
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| 11 |
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| 12 |
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| 13 | Very high energy (VHE) GRB observations have the potential to constrain the current GRB models
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| 14 | on both the prompt and extended phases of GRB emission~\cite{HARTMANN,MANNHEIM,SALOMON}.
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| 15 | Models based on both internal and external shocks predicts VHE fluence comparable to,
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| 16 | or in certain situations stronger than, the keV-MeV radiation,
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| 17 | with duration ranging from shorter than the keV-MeV burst to extended TeV afterglows~\cite{DERMER, PILLA, ZHANG1}.
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| 18 |
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| 19 | \par
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| 20 |
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| 21 | In many publications, the possibility that more energetic $\gamma$-rays come along with the
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| 22 | (low-energy) GRB, have been explored. Proton-synchrotron emission~\cite{TOTANI} have been suggested
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| 23 | as well as photon-pion production~\cite{WAXMAN,BAHCALL,BOETTCHER} and inverse-Compton scattering
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| 24 | in the burst environment~\cite{MESZAROS93,CHIANG,PILLA,ZHANG2}.
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| 25 | Long-term HE $\gamma$ emission from accelerated protons in the forward-shock has been predicted in~\cite{LI}. This model predicts GeV inverse Compton emission even one day after the burst.
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| 26 | Even considering pure electron-synchrotron radiation predicts measurable GeV emission for a significant fraction of GRBs~\cite{ZHANG2}. In order to be able to describe prompt synchrotron optical flashes (like observed in GRB990123 by ROTSE), GeV--TeV emission by inverse Compton scattering of the MeV photons should be produced at the same time~\cite{BELOBORODOV}.\\
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| 27 |
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| 28 | GeV emission in GRBs is particularly sensitive to the Lorentz factor and the photon density of the emitting material -
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| 29 | and thus to the distance of the radiating shock from the source - due to the \linebreak
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| 30 | $\gamma~\gamma \rightarrow$ \textit{e$^+$~e$^-$} absorption in the emission region. Direct comparison of the prompt GRB flux at $\sim$ 10\,GeV and $\sim$ 100\,keV may allow to determine the magnetic field strength~\cite{ASAF2}.
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| 31 |
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| 32 | \par
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| 33 |
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| 34 | Several attempts have been made in the past to observe GRBs in the GeV range,
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| 35 | each indicating some excess over background but without stringent evidence.
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| 36 | The only significant detection was performed by \eg which detected seven GRBs emitting high energy (HE)
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| 37 | photons in the 100\,MeV to 18\,GeV range~\cite{EGRET}. The data shows no evidence of a HE cut-off
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| 38 | in the GRB spectrum~\cite{DINGUS}. Recent results indicate that the spectrum of some GRBs contains a very hard, luminous, long-duration component~\cite{GONZALES}.
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| 39 | There have been results suggesting gamma rays beyond the GeV range from the TIBET air shower array
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| 40 | in coincidence with BATSE bursts~\cite{AMENOMORI}, rapid follow-up observations by the
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| 41 | Whipple Air Cherenkov Telescope~\cite{CONNAUGHTON1}, and coincident and monitoring studies by HEGRA-AIROBICC~\cite{PADILLA}, Whipple~\cite{CONNAUGHTON2} and the Milagro prototype Milagrito~\cite{MILAGRO}. The GRAND array has reported some excess of observed muons during seven BATSE bursts~\cite{GRAND}. In this context, especially the publication from the TASC detector on \eg is important~\cite{GONZALES}, finding a HE spectral component presumably due to ultra-relativistic acceleration of hadrons and producing a spectral index of $-1$ with no cut-off up to the detector energy limit (200\,MeV).\\
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| 42 |
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| 43 | Concerning estimates about the \ma observability of GRBs, a very detailed study of GRB spectra obtained from the
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| 44 | third and fourth \ba catalogue has been made in~\cite{ICRC,NICOLA}. The spectra were extrapolated to GeV energies
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| 45 | with a simple continuation of the observed high-energy power law behaviour and the calculated fluxes compared with \ma sensitivities. Setting conservative cuts on observation times and significances,
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| 46 | and assuming an energy threshold of 15~GeV, a GRB detection rate of $0.5-2$ per year
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| 47 | was obtained for an assumed observation delay between 15 and 60 sec. and a \ba trigger rate ($\sim$\,360/year).
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| 48 |
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| 49 | Taking into account the local rate of GRBs estimated in~\cite{GUETTA}, late afterglow emission from few tens of GRBs per year
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| 50 | should be observable above our energy threshold. The model of~\cite{ASAF2} predict delayed GeV emission that should be significantly detectable by MAGIC in 100\,seconds.
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| 51 |
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| 52 | \subsection{Observation of XRFs}
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| 53 |
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| 54 | While the major energy from the prompt GRBs is emitted in $\gamma$-rays ($E_p \sim$ 200~keV), XRFs are characterized
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| 55 | by peak energies below 50~keV and a dominant X-ray fluence. Because of similar properties a connection between XRFs and GRBs is
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| 56 | suggested. The most popular theories say that XRFs are produced from GRBs observed ''off-axis''.
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| 57 | Alternatively, an increase of the baryon load within the fireball itself or low efficiency shocks can produce XRFs.
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| 58 | If there is a connection between the XRFs and GRBs, they should originate at rather low redshifts (z $<$ 0.6).\\
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| 59 |
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| 60 | Gamma-ray satellites react in the same way to XRFs and GRBs. In case of a detection the coordinates are distributed
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| 61 | to other observatories (see section 2.1). Only from later analysis the difference can be established.
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| 62 |
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| 63 | \par
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| 64 |
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| 65 | In this case we include also the observation of XRFs by MAGIC in our proposal.
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| 66 |
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| 67 | \subsection{Observation of SGRs}
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| 68 |
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| 69 | Soft Gamma Repeaters (SGRs) are extremely rare strong magnetic neutron stars that periodically emit $\gamma$-rays. Only four identified SGRs were discovered in the last 20 years: SGR0526-66, SGR1806-20, SGR1900+14, SGR1627-41. GRBs and SGRs can be explained with an unique processing gamma jet model observed at different beam-angle and at different ages.\\
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| 70 |
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| 71 | The BAT instrument on the SWIFT satellite triggered on an outburst from SGR1806-20 on 30. January 2005. The fluence was $\sim$ 1$\times$10$^{-5}$erg/cm$^2$(15-350keV). This event was five orders of magnitude smaller than the giant flare from this source on the 27. December 2004. If a giant flare from SGR occurs as SGR1806-20, MAGIC would be able to detect the 100\,seconds delayed $\gamma$-emission from the source.
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