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E-ASTROGAM

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ASTROGAM
The payload of e-ASTROGAM (gamma-ray telescope)
Mission typeAstronomy

The ASTROGAM concept consists in the use of a silicon tracker to record the Compton interactions and the pair production by gamma rays in the MeV-GeV region. The energy of the final state particles can possibly measured by a calorimeter.

e-ASTROGAM[1] is a proposed space mission with the purpose of measuring gamma-rays from astrophysical sources in the energy range from 300 keV to a few GeV.[2] e-ASTROGAM reaches a sensitivity one-two orders of magnitude larger than its predecessor, the detector COMPTEL on the Compton Gamma Ray Observatory (CGRO), and offers as a new feature the capability of fast triggers for astrophysical transients.[3]

The mission will provide unique data of significant interest to a broad astronomical community, complementary to powerful observatories such as LIGO-Virgo-GEO600-KAGRA, SKA, ALMA, E-ELT, TMT, LSST, JWST, Athena, CTA, IceCube, KM3N, LISA.[4] It will sample the right energies to explore the highest-energy electromagnetic counterparts of gravitational wave events, localizing possible corresponding gamma-ray bursts.

Multiwavelength and Multimessenger Science with e-ASTROGAM

e-ASTROGAM is made of 56 Silicon planes, about 1 m^2 each, which record Compton interactions and pair production events induced by cosmic photons, by an anticoincidence detector and by a calorimeter.

The international collaboration working to e-ASTROGAM involves more than 400 scientists working in institutions from Argentina, Brazil, Bulgaria, China, Croatia, Czech Republic, Denmark, Ireland, Italy, Finland, France, Germany, Japan, Mexico, Norway, Poland, Portugal, Russia, Spain, Sweden, Switzerland, United States.

e-ASTROGAM deployed.
The e-ASTROGAM satellite deployed
e-ASTROGAM deployed.
Scheme for science topics and properties of the mission.

References

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  1. ^ "E-ASTROGAM". Archived from the original on 2020-05-05. Retrieved 2016-11-09.
  2. ^ De Angelis, A.; Tatischeff, V.; Tavani, M.; Oberlack, U.; Grenier, I.; Hanlon, L.; Walter, R.; Argan, A.; von Ballmoos, P.; Bulgarelli, A.; Donnarumma, I.; Hernanz, M.; Kuvvetli, I.; Pearce, M.; Zdziarski, A.; Aboudan, A.; Ajello, M.; Ambrosi, G.; Bernard, D.; Bernardini, E.; Bonvicini, V.; Brogna, A.; Branchesi, M.; Budtz-Jorgensen, C.; Bykov, A.; Campana, R.; Cardillo, M.; Coppi, P.; De Martino, D.; et al. (2017). "The e-ASTROGAM mission". Experimental Astronomy. 44: 25–82. arXiv:1611.02232. doi:10.1007/s10686-017-9533-6. S2CID 118633829.
  3. ^ Knödlseder, Jürgen (2016). "The future of gamma-ray astronomy". Comptes Rendus Physique. 17 (6): 663–678. arXiv:1602.02728. Bibcode:2016CRPhy..17..663K. doi:10.1016/j.crhy.2016.04.008.
  4. ^ De Angelis, A.; Tatischeff, V.; Grenier, I.A.; McEnery, J.; Mallamaci, M.; Tavani, M.; Oberlack, U.; Hanlon, L.; Walter, R.; Argan, A.; von Ballmoos, P.; Bulgarelli, A.; Bykov, A.; Hernanz, M.; Kanbach, G.; Kuvvetli, I.; Pearce, M.; Zdziarski, A.; Conrad, J.; Ghisellini, G.; Harding, A.; Isern, J.; Leising, M.; Longo, F.; Madejski, G.; Martinez, M.; Mazziotta, M.N.; Paredes, J.M.; Pohl, M.; et al. (2018). "Science with e-ASTROGAM". Journal of High Energy Astrophysics. 19: 1–106. arXiv:1711.01265. doi:10.1016/j.jheap.2018.07.001. S2CID 119367932.