source: trunk/MagicSoft/GRB-Proposal/ScientificCase.tex@ 7109

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1%% Requested observation time
2\section{Requested observation time}
3We espect up to two alerts per month. Maximum time requested
4for a single alert is 5h.
5
6\section{Scientific Case}
7
8\subsection{Observation of GRBs}
9
10The support structure and mirrors of the \ma telescope were designed to be exceptionally light in order to
11react quickly to GRB alerts from satellites. The aim was to turn the telescope toward the burst position
12within 30\,s~\cite{design,PETRY},
13in order to have a fair chance to detect a burst when the prompt $\gamma$--emission is still ongoing.
14During the commissioning phase, it could be proven that the goal was achieved.
15The telescope is able to turn $360^\circ$ in azimuth within 20\,s and $90^\circ$ in zenith within 10\,s.\\
16
17Very high energy (VHE) GRB observations have the potential to constrain the current GRB models
18on both the prompt and the extended phase of GRB emission~\cite{HARTMANN,MANNHEIM}.
19Models based on either internal or external shocks predict VHE gamma-ray fluences comparable to,
20or in certain situations stronger than, the keV-MeV radiation,
21with durations ranging from shorter than the keV-MeV burst to extended TeV
22afterglows~\cite{DERMER, PILLA, ZHANG1, RAZZAQUE}.
23
24\par
25
26Possible causes range from proton-synchrotron emission~\cite{TOTANI} to
27photon-pion production~\cite{WAXMAN,BOETTCHER} and inverse-Compton scattering
28in the burst environment~\cite{MESZAROS93,CHIANG,PILLA,ZHANG2,BELOBORODOV}.
29A long-term high energy (HE) $\gamma$-emission can come from accelerated protons in the forward-shock, as predicted in~\cite{LI}.
30This model predicts GeV inverse Compton emission up to one day after the burst.
31Even considering pure electron-synchrotron radiation, measurable GeV-emission for a significant
32fraction of GRBs is predicted~\cite{ZHANG2}.
33
34\par
35
36GeV-emission in GRBs is particularly sensitive to the Lorentz factor and the photon density of the emitting material -- and thus to the distance of the radiating shock from the source -- due to the $\gamma \gamma \rightarrow \textrm{e}^+\textrm{e}^-$ 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}.\\
37
38
39Several attempts were made in the past to observe GRBs in the GeV range,
40each indicating some excess over background but without stringent evidence.
41The only significant detections were performed by \eg, that was able to observe seven GRBs emitting HE photons with energies between 100\,MeV and 18\,GeV~\cite{EGRET, DINGUS1}. The data shows a HE spectral component presumably due to the ultra-relativistic acceleration of hadrons and producing a spectral index of $-1$ with no cut-off up to the TASC detector energy limit at 200\,MeV~\cite{DINGUS2, GONZALES}. Recent results indicate that the spectrum of some GRBs contains a very hard, luminous, long-duration component~\cite{GONZALES}.
42There have been results suggesting gamma rays beyond the GeV range from the TIBET air shower array in coincidence with BATSE bursts~\cite{AMENOMORI}, rapid follow-up observations by the 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}.
43The GRAND array has reported some excess of observed muons during seven BATSE bursts~\cite{GRAND}.\\
44
45To estimate the observability of GRB by \ma, sources of the
46third and fourth \ba catalogue were studied~\cite{ICRC,NICOLA}. Their spectra were extended to GeV
47energies with a simple power-law and using the observed high-energy spectral index: the extrapolated fluxes
48were at last compared with \ma sensitivities. Setting conservative cuts on observation times and significances,
49and assuming an energy threshold of 15~GeV, a 5\,$\sigma$-signal rate of $0.5-2$ per year
50was obtained for an assumed observation delay between 15 and 60\,s and a \ba trigger rate
51($\sim$\,360/year). As the \sw alert rate is about a factor~2 lower, including even fainter bursts than
52those observed by \ma, this number still have to be lowered.
53
54Taking into account the local rate of GRBs estimated in~\cite{GUETTA}, late afterglow emission from a
55few tens of GRBs per year should be observable over the whole sky above our energy threshold.
56The model of~\cite{ASAF2} predicts delayed GeV-emission that should be significantly detectable by \ma
57in 100\,s.
58
59\subsection{Observation of XRFs}
60
61While the major energy from the prompt GRBs is emitted in $\gamma$-rays with a peak energy of 200\,keV,
62X-ray flashes (XRFs) are characterized
63by peak energies below 50~keV and a dominant X-ray fluence. Because of similar properties, a connection
64between XRFs and GRBs is suggested.
65Some theories~\cite{DADO} suggest that XRFs are produced from GRBs observed ''off-axis''.
66Alternatively, an increase of the baryon load within the fireball itself~\cite{HUANG} or low efficiency
67shocks~\cite{BARRAUD} could produce XRFs.
68If there is a connection between XRFs and GRBs, they should originate at rather low redshifts ($z < 0.6$)
69because otherwise, the XRF energies would not fit into the observed correlation
70between GRB peak energy and isotropic energy release~\cite{LEVAN}.
71
72\subsection{Observation of SGRs}
73
74Soft Gamma Repeaters (SGRs) are believed to be extremely rare strong magnetic neutron stars that
75periodically emit $\gamma$-rays. Only four identified SGRs were discovered in the last 20 years:
76SGR0526-66, SGR1806-20, SGR1900+14, SGR1627-41.
77GRBs and SGRs can be explained within the same gamma jet model where the jet is observed at different
78beam-angles and different times~\cite{FARGION}.\\
79
80The BAT instrument on the SWIFT satellite triggered on an outburst from SGR1806-20 on January $30^{\mathrm{th}}$, 2005.
81The fluence was about $10^{-5}\mathrm{erg}\cdot\mathrm{cm}^{-2}$ in the range between 15 and 350\,keV.
82This event was five orders of magnitude smaller than the giant flare from this source on the December 27$^{\mathrm{th}}$, 2004~\cite{GCN3002}.
83MAGIC has enough sensitivity for observing events with fluences bigger than $2.5 \times 10^{-2}\mathrm{erg}\cdot\mathrm{cm}^{-2}\mathrm{s}^{-1}$ at 100\,keV, when a spectral index of $-2.0$ and 100\,s of observation time are assumed.
84Therefore if an SGR as the giant flare of SGR1806-20 occurs, MAGIC would be able to detect its $\gamma$-ray emission.\\
85
86Gamma-ray satellites react in the same way to XRFs, SGRs and GRBs.
87In case of a detection the coordinates are distributed to other observatories (see section 2.1). Only from later analysis the difference can be established. We include therefore the observation of XRFs and SGRs by \ma in our proposal.
88
89
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