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Prospects in space-based Gamma-Ray Astronomy Jürgen Knödlseder Centre d’Etude Spatiale des Rayonnements, Toulouse, France On behalf of the European Gamma-Ray community
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Gamma-Ray Astronomy in Europe Europe has a long tradition in gamma-ray astronomy and is actually the world leader in the field (INTEGRAL) Maintain Europe’s leading role in gamma-ray astronomy Europe has a long tradition in gamma-ray astronomy and is actually the world leader in the field (INTEGRAL) Maintain Europe’s leading role in gamma-ray astronomy Why Gamma-Ray Astronomy ? Specific character of emission processes w/r to other wavebands (non-thermal, particle acceleration, particle & nuclear physics) Diversity of emission sites (Sun, compact binaires, pulsars, SNRs, Galaxy/ISM, AGNs, GRBs, CB) Penetrating power of gamma-ray photons Why Gamma-Ray Astronomy ? Specific character of emission processes w/r to other wavebands (non-thermal, particle acceleration, particle & nuclear physics) Diversity of emission sites (Sun, compact binaires, pulsars, SNRs, Galaxy/ISM, AGNs, GRBs, CB) Penetrating power of gamma-ray photons Seminar : Prospects in space-based Gamma-Ray Astronomy for Europe March 18th, 2005 (Rome) http://www.cesr.fr/~jurgen/rome2005/ Presentation of the conclusions Seminar : Prospects in space-based Gamma-Ray Astronomy for Europe March 18th, 2005 (Rome) http://www.cesr.fr/~jurgen/rome2005/ Presentation of the conclusions
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Science themes Cosmic accelerators The most dynamic and powerful sites in the Universe Accretion on compact objects Accretion on compact objects Rotation of neutron stars Rotation of neutron stars Explosions and shocks Explosions and shocks Binaries µ-blazars AGN GRB SNR Stellar winds Pulsars Magnetars Gravitational collapse Gravitational collapse Core-collapse SN GRB Thermonuclear explosions Thermonuclear explosions Type Ia SN Thermonuclear runaways Thermonuclear runaways Novae X-ray bursts Cosmic explosions The most violent events in the Universe
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Cosmic accelerators Black holes : understanding the accretion-ejection physics How is the energy reservoir transformed into relativistic particles ? How is the energy reservoir transformed into relativistic particles ? Jet formation and collimation ? Jet formation and collimation ? What triggers the outbursts ? What triggers the outbursts ? Composition of accelerated plasmas ? Composition of accelerated plasmas ? Nature of the radiation process ? Nature of the radiation process ? Study broad-band SED in various states ; probe the universality of hard powerlaw tails Measure polarisation of emission components Search for pair annihilation and nuclear line features Zdziarski & Gierlinski (2004) Fender et al. (2004)
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Cosmic accelerators The origin of galactic soft -ray emission INTEGRAL : ~ 90% of the galactic hard X-ray emission is resolved INTEGRAL : ~ 90% of the galactic hard X-ray emission is resolved Spectral change around ~ 300 keV (Comptonisation powerlaw) Spectral change around ~ 300 keV (Comptonisation powerlaw) What is the origin of the emission at soft -ray energies ? What is the origin of the emission at soft -ray energies ? Lebrun et al. (2003) Kinzer et al. (1999) Search for hard tails in soft -ray sources Resolve the ‘diffuse’ galactic soft -ray emission
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Cosmic accelerators The origin of the cosmic soft -ray background INTEGRAL : ~ 20% of the sources in the 2 nd IBIS catalogue are of extragalactic origin 24 Seyferts, 5 Blazars, 5 AGN, 3 clusters INTEGRAL : ~ 20% of the sources in the 2 nd IBIS catalogue are of extragalactic origin 24 Seyferts, 5 Blazars, 5 AGN, 3 clusters So far, only ~ 1 % of the cosmic soft -ray background is resolved So far, only ~ 1 % of the cosmic soft -ray background is resolved Weidenspointner (1998) AGN & cosmic background Bassani et al. (2005) Measure the soft -ray SED of AGN - high-energy cut-offs - hard tails Resolve the soft -ray background Determine the nature of the radiation process - polarisation measurements - annihilation features
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Cosmic accelerators Probing particle acceleration in the most extreme magnetic fields INTEGRAL : discovery of hard emission tails in SGR 1806-20 and AXPs INTEGRAL : discovery of hard emission tails in SGR 1806-20 and AXPs Emission mechanism ? Emission mechanism ? Energy cut-off ? QED effects (photon splitting) Energy cut-off ? QED effects (photon splitting) Cyclotron features ? Cyclotron features ? summed bursts / 1000 quiescent Molkov et al. (2005) Kuiper et al. (2004) Measure the soft -ray SED of magnetars - high-energy cut-off - cyclotron features
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Cosmic explosions Type Ia SN : Identifying the progenitors and probing the explosion physics Distinguish progenitor scenarios direct measurement of 56 Ni mass (single / double degenerate) Distinguish progenitor scenarios direct measurement of 56 Ni mass (single / double degenerate) Distinguish explosion scenarios measure line shape evolution Distinguish explosion scenarios measure line shape evolution Gomez-Gomar et al. (1998) Milne et al. (2004) Measure -ray line lightcurves and profiles in nearby (< 100 Mpc) SN Ia Search for radioactive decay signatures in galactic SNR (incl. e + )
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Cosmic explosions From stars to compact objects : understanding core collapse explosions INTEGRAL : 44 Ti ejection velocity in Cas A v e > 1000 km s -1 INTEGRAL : 44 Ti ejection velocity in Cas A v e > 1000 km s -1 Fe-core material acceleration ? Fe-core material acceleration ? Jet formation ? Jet formation ? What drives the supernova explosion ? What drives the supernova explosion ? Measure -ray line lightcurves and profiles in nearby (< 10 Mpc) core-collapse supernovae Leising & Share (1990) Study -ray lines in galactic SNR ( 44 Ti, 26 Al, 60 Fe) Diehl & Timmes (1997)
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Cosmic explosions Unveiling the origin of galactic positrons INTEGRAL : the bulk of positrons originates from a pure bulge population ; they annihilate in a warm and partially ionised ISM INTEGRAL : the bulk of positrons originates from a pure bulge population ; they annihilate in a warm and partially ionised ISM What is this mysterious bulge source ? What is this mysterious bulge source ? Jean et al. (2005) Knödlseder et al. (2005) High-resolution mapping of the galactic bulge region Probe annihilation medium around positron sources
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Mission requirements Sensitivity leap in the soft gamma-ray band Sensitivity leap in the soft gamma-ray band Adequate angular resolution for counterpart identification Adequate angular resolution for counterpart identification Capability to measure polarisation Capability to measure polarisation Energy band50 keV - 2 MeV Energy band50 keV - 2 MeV FOV30 arcmin FOV30 arcmin Continuum sensitivity10 -8 ph cm -2 s -1 keV -1 (10 6 s, 3 ) Continuum sensitivity10 -8 ph cm -2 s -1 keV -1 (10 6 s, 3 ) Narrow line sensitivity5 x 10 -7 ph cm -2 s -1 (10 6 s, 3 ) Narrow line sensitivity5 x 10 -7 ph cm -2 s -1 (10 6 s, 3 ) Energy resolution2 keV @ 600 keV Energy resolution2 keV @ 600 keV Angular resolutionarcmin Angular resolutionarcmin Polarisation1 % @ 10 mCrab (10 6 s, 3 ) Polarisation1 % @ 10 mCrab (10 6 s, 3 ) Mission parameters
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The Gamma-Ray Imager … an artist’s Cosmic Vision
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