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2. Gamma- and Cosmic-Ray Observations with the GAMMA-400 Gamma-Ray Telescope

Author

Topchiev, N. P., Galper, A. M., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bakaldin, A. V., Cherniy, R. A., Chernysheva, I. V., Gudkova, E. N., Gusakov, Yu. V., Dalkarov, O. D., Egorov, A. E., Kheymits, M. D., Korotkov, M. G., Leonov, A. A., Malinin, A. G., Mikhailov, V. V., Mikhailova, A. V., Minaev, P. Yu., Pappe, N. Yu., Razumeyko, M. V., Runtso, M. F., Stozhkov, Yu. I., Suchkov, S. I., and Yurkin, Yu. T.

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

The future space-based GAMMA-400 gamma-ray telescope will operate onboard the Russian astrophysical observatory in a highly elliptic orbit during 7 years to observe Galactic plane, Galactic Center, Fermi Bubbles, Crab, Vela, Cygnus X, Geminga, Sun, and other regions and measure gamma- and cosmic-ray fluxes. Observations will be performed in the point-source mode continuously for a long time (~100 days). GAMMA-400 will measure gamma rays in the energy range from ~20 MeV to several TeV and cosmic-ray electrons + positrons up to several tens TeV. GAMMA-400 instrument will have very good angle and energy resolutions, high separation efficiency of gamma rays from cosmic-ray background, as well as electrons + positrons from protons. The main feature of GAMMA-400 is the unprecedented angular resolution for energies >30 GeV better than the space-based and ground-based gamma-ray telescopes by a factor of 5-10. GAMMA-400 observations will permit to resolve gamma rays from annihilation or decay of dark matter particles, identify many discrete sources, clarify the structure of extended sources, specify the data on cosmic-ray electron + positron spectra., Comment: Submitted to Advances in Space Research, special issue "Astrophysics of CRs", 31 pages, 22 figures

Published
2021
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3. Cosmophysical Research with GAMMA-400

Author

Topchiev, N. P., Galper, A. M., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bakaldin, A. V., Chernysheva, I. V., Dalkarov, O. D., Egorov, A. E., Kheymits, M. D., Korotkov, M. G., Leonov, A. A., Leonova, S. A., Malinin, A. G., Mikhailov, V. V., Minaev, P. Yu., Pappe, N. Yu., Suchkov, S. I., and Yurkin, Yu. T.

Published
2023
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6. Capabilities of the GAMMA-400 gamma-ray telescope to detect gamma-ray bursts from lateral directions

Author

Leonov, A A, Galper, A M, Topchiev, N P, Arkhangelskaja, I V, Arkhangelskiy, A I, Bakaldin, A V, Chernysheva, I V, Dalkarov, O D, Egorov, A E, Kheymits, M D, Korotkov, M G, Malinin, A G, Mayorov, A G, Mikhailov, V V, Mikhailova, A V, Minaev, P Yu, Pappe, N Yu, Picozza, P, Sparvoli, R, Stozhkov, Yu I, Suchkov, S I, and Yurkin, Yu T

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

The currently developing space-based gamma-ray telescope GAMMA-400 will measure the gamma-ray and electron + positron fluxes using the main top-down aperture in the energy range from ~20 MeV to several TeV in a highly elliptic orbit (without shading the telescope by the Earth and outside the radiation belts) continuously for a long time. The instrument will provide fundamentally new data on discrete gamma-ray sources, gamma-ray bursts (GRBs), sources and propagation of Galactic cosmic rays and signatures of dark matter due to its unique angular and energy resolutions in the wide energy range. The gamma-ray telescope consists of the anticoincidence system (AC), the converter-tracker (C), the time-of-flight system (S1 and S2), the position-sensitive and electromagnetic calorimeters (CC1 and CC2), scintillation detectors (S3 and S4) located above and behind the CC2 calorimeter and lateral detectors (LD) located around the CC2 calorimeter. In this paper, the capabilities of the GAMMA-400 gamma-ray telescope to measure fluxes of GRBs from lateral directions of CC2 are analyzed using Monte-Carlo simulations. The analysis is based on off-line second-level trigger construction using signals from S3, CC2, S4 and LD detectors. For checking the numerical algorithm the data from space-based GBM and LAT instruments of the Fermi experiment are used, namely, three long bursts: GRB 080916C, GRB 090902B, GRB 090926A and one short burst GRB 090510A. The obtained results allow us to conclude that from lateral directions the GAMMA-400 space-based gamma-ray telescope will reliably measure the spectra of bright GRBs in the energy range from ~10 to ~100 MeV with the on-axis effective area of about 0.13 m2 for each of the four sides of CC2 and total field of view of about 6 sr., Comment: 22 pages, 18 figures, the paper will be submitted to Advances in Space Research

Published
2021

7. Detectability of dark matter subhalos by means of the GAMMA-400 telescope

Author

Egorov, A. E., Galper, A. M., Topchiev, N. P., Leonov, A. A., Suchkov, S. I., Kheymits, M. D., and Yurkin, Yu. T.

Subjects
Astrophysics - High Energy Astrophysical Phenomena, High Energy Physics - Phenomenology
Abstract

We investigated the detectability of Galactic subhalos with masses $(10^6-10^9)M_{\odot}$ formed by annihilating WIMP dark matter by the planned GAMMA-400 gamma-ray telescope. The inner structure of dark matter subhalos and their distribution in the Galaxy were taken from corresponding simulations. We showed that the expected gamma-ray flux from subhalos strongly depends on WIMP mass and subhalo concentration, but less strongly depends on the subhalo mass. In an optimistic case we may expect the flux of 10-100 ph/year above 100 MeV from the closest and most massive subhalos, which would be detectable sources for GAMMA-400. However, resolving the inner structure of subhalos might be possible only by the joint analysis of the future GAMMA-400 data and data from other telescopes due to smallness of fluxes. Also we considered the recent subhalo candidates 3FGL J2212.5+0703 and J1924.8-1034 within the framework of our model. We concluded that it is very unlikely that these sources belong to the subhalo population., Comment: Was presented at International Symposium on Cosmic Rays and Astrophysics (ISCRA-2017), 20-22 June 2017, Moscow, Russia

Published
2017
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8. High-energy gamma-ray studying with GAMMA-400

Author

Topchiev, N. P., Galper, A. M., Bonvicini, V., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bakaldin, A. V., Bobkov, S. G., Dalkarov, O. D., Egorov, A. E., Gusakov, Yu. V., Hnatyk, B. I., Kadilin, V. V., Kheymits, M. D., Korepanov, V. E., Leonov, A. A., Mikhailov, V. V., Moiseev, A. A., Moskalenko, I. V., Naumov, P. Yu., Picozza, P., Runtso, M. F., Serdin, O. V., Sparvoli, R., Spillantini, P., Stozhkov, Yu. I., Suchkov, S. I., Taraskin, A. A., Yurkin, Yu. T., and Zverev, V. G.

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - High Energy Astrophysical Phenomena
Abstract

Extraterrestrial gamma-ray astronomy is now a source of new knowledge in the fields of astrophysics, cosmic-ray physics, and the nature of dark matter. The next absolutely necessary step in the development of extraterrestrial high-energy gamma-ray astronomy is the improvement of the physical and technical characteristics of gamma-ray telescopes, especially the angular and energy resolutions. Such a new generation telescope will be GAMMA-400. GAMMA-400, currently developing gamma-ray telescope, together with X-ray telescope will precisely and detailed observe in the energy range of ~20 MeV to ~1000 GeV and 3-30 keV the Galactic plane, especially, Galactic Center, Fermi Bubbles, Crab, Cygnus, etc. The GAMMA- 400 will operate in the highly elliptic orbit continuously for a long time with the unprecedented angular (~0.01{\deg} at E{\gamma} = 100 GeV) and energy (~1% at E{\gamma} = 100 GeV) resolutions better than the Fermi-LAT, as well as ground gamma-ray telescopes, by a factor of 5-10. GAMMA-400 will permit to resolve gamma rays from annihilation or decay of dark matter particles, identify many discrete sources (many of which are variable), to clarify the structure of extended sources, to specify the data on the diffuse emission., Comment: 8 pages, 9 figures, ICRC2017

Published
2017

9. GAMMA-400 Gamma-Ray Observations in the GeV and TeV Energy Range

Author

Topchiev, N. P., Galper, A. M., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bakaldin, A. V., Cherniy, R. A., Chernysheva, I. V., Dalkarov, O. D., Egorov, A. E., Kheymits, M. D., Korotkov, M. G., Leonov, A. A., Malinin, A. G., Mikhailov, V. V., Minaev, P. Yu., Pappe, N. Yu., Runtso, M. F., Smirnov, A. I., Stozhkov, Yu. I., Suchkov, S. I., and Yurkin, Yu. T.

Published
2021
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10. Improvement of the GAMMA-400 physical scheme for precision gamma-ray emission investigations

Author

Leonov, A. A., Galper, A. M., Topchiev, N. P., Bonvicini, V., Adriani, O., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bakaldin, A. V., Bobkov, S. G., Boezio, M., Dalkarov, O. D., Egorov, A. E., Glushkov, N. A., Gorbunov, M. S., Gusakov, Yu. V., Hnatyk, B. I., Kadilin, V. V., Kaplin, V. A., Kheymits, M. D., Korepanov, V. E., Longo, F., Mikhailov, V. V., Mocchiutti, E., Moiseev, A. A., Moskalenko, I. V., Naumov, P. Yu., Picozza, P., Runtso, M. F., Serdin, O. V., Sparvoli, R., Spillantini, P., Stozhkov, Yu. I., Suchkov, S. I., Taraskin, A. A., Tavani, M., Yurkin, Yu. T., and Zverev, V. G.

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - High Energy Astrophysical Phenomena
Abstract

The main goal for the GAMMA-400 gamma-ray telescope mission is to perform a sensitive search for signatures of dark matter particles in high-energy gamma-ray emission. Measurements will also concern the following scientific goals: detailed study of the Galactic center region, investigation of point and extended gamma-ray sources, studies of the energy spectra of Galactic and extragalactic diffuse emissions. To perform these measurements the GAMMA-400 gamma-ray telescope possesses unique physical characteristics for energy range from ~20 MeV to ~1000 GeV in comparison with previous and current space and ground-based experiments. The major advantage of the GAMMA-400 instrument is excellent angular and energy resolutions for gamma-rays above 10 GeV. The gamma-ray telescope angular and energy resolutions for the main aperture at 100-GeV gamma rays are ~0.01 deg and ~1%, respectively. The special goal is to improve physical characteristics in the low- energy range from ~20 MeV to 100 MeV. Minimizing the amount of dead matter in the telescope aperture allows us to obtain the angular and energy resolutions better in this range than in current space missions. The gamma-ray telescope angular resolution at 50-MeV gamma rays is better than 5 deg and energy resolution is ~10%. We report the method providing these results., Comment: XXV ECRS 2016 Proceedings - eConf C16-09-04.3

Published
2016

11. GAMMA-400 gamma-ray observatory

Author

Topchiev, N. P., Galper, A. M., Bonvicini, V., Adriani, O., Aptekar, R. L., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bakaldin, A. V., Bergstrom, L., Berti, E., Bigongiari, G., Bobkov, S. G., Boezio, M., Bogomolov, E. A., Bonechi, L., Bongi, M., Bottai, S., Castellini, G., Cattaneo, P. W., Cumani, P., Dalkarov, O. D., Dedenko, G. L., De Donato, C., Dogiel, V. A., Finetti, N., Gascon, D., Gorbunov, M. S., Gusakov, Yu. V., Hnatyk, B. I., Kadilin, V. V., Kaplin, V. A., Kaplun, A. A., Kheymits, M. D., Korepanov, V. E., Larsson, J., Leonov, A. A., Loginov, V. A., Longo, F., Maestro, P., Marrocchesi, P. S., Martinez, M., Menshenin, A. L., Mikhailov, V. V., Mocchiutti, E., Moiseev, A. A., Mori, N., Moskalenko, I. V., Naumov, P. Yu., Papini, P., Paredes, J. M., Pearce, M., Picozza, P., Rappoldi, A., Ricciarini, S., Runtso, M. F., Ryde, F., Serdin, O. V., Sparvoli, R., Spillantini, P., Stozhkov, Yu. I., Suchkov, S. I., Taraskin, A. A., Tavani, M., Tiberio, A., Tyurin, E. M., Ulanov, M. V., Vacchi, A., Vannuccini, E., Vasilyev, G. I., Ward, J. E., Yurkin, Yu. T., Zampa, N., Zirakashvili, V. N., and Zverev, V. G.

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

The GAMMA-400 gamma-ray telescope with excellent angular and energy resolutions is designed to search for signatures of dark matter in the fluxes of gamma-ray emission and electrons + positrons. Precision investigations of gamma-ray emission from Galactic Center, Crab, Vela, Cygnus, Geminga, and other regions will be performed, as well as diffuse gamma-ray emission, along with measurements of high-energy electron + positron and nuclei fluxes. Furthermore, it will study gamma-ray bursts and gamma-ray emission from the Sun during periods of solar activity. The energy range of GAMMA-400 is expected to be from ~20 MeV up to TeV energies for gamma rays, up to 20 TeV for electrons + positrons, and up to 10E15 eV for cosmic-ray nuclei. For high-energy gamma rays with energy from 10 to 100 GeV, the GAMMA-400 angular resolution improves from 0.1{\deg} to ~0.01{\deg} and energy resolution from 3% to ~1%; the proton rejection factor is ~5x10E5. GAMMA-400 will be installed onboard the Russian space observatory., Comment: 8 pages, 2 figures, 2 tables, submitted to the proceedings of ICRC2015

Published
2015

12. A separation of electrons and protons in the GAMMA-400 gamma-ray telescope

Author

Leonov, A. A., Galper, A. M., Bonvicini, V., Topchiev, N. P., Adriani, O., Aptekar, R. L., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bergstrom, L., Berti, E., Bigongiari, G., Bobkov, S. G., Boezio, M., Bogomolov, E. A., Bonechi, S., Bongi, M., Bottai, S., Castellini, G., Cattaneo, P. W., Cumani, P., Dedenko, G. L., De Donato, C., Dogiel, V. A., Gorbunov, M. S., Gusakov, Yu. V., Hnatyk, B. I., Kadilin, V. V., Kaplin, V. A., Kaplun, A. A., Kheymits, M. D., Korepanov, V. E., Larsson, J., Loginov, V. A., Longo, F., Maestro, P., Marrocchesi, P. S., Mikhailov, V. V., Mocchiutti, E., Moiseev, A. A., Mori, N., Moskalenko, I. V., Naumov, P. Yu., Papini, P., Pearce, M., Picozza, P., Popov, A. V., Rappoldi, A., Ricciarini, S., Runtso, M. F., Ryde, F., Serdin, O. V., Sparvoli, R., Spillantini, P., Suchkov, S. I., Tavani, M., Taraskin, A. A., Tiberio, A., Tyurin, E. M., Ulanov, M. V., Vacchi, A., Vannuccini, E., Vasilyev, G. I., Yurkin, Yu. T., Zampa, N., Zirakashvili, V. N., and Zverev, V. G.

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics, Physics - Instrumentation and Detectors
Abstract

The GAMMA-400 gamma-ray telescope is intended to measure the fluxes of gamma rays and cosmic-ray electrons and positrons in the energy range from 100 MeV to several TeV. Such measurements concern with the following scientific goals: search for signatures of dark matter, investigation of gamma-ray point and extended sources, studies of the energy spectra of Galactic and extragalactic diffuse emission, studies of gamma-ray bursts and gamma-ray emission from the active Sun, as well as high-precision measurements of spectra of high-energy electrons and positrons, protons, and nuclei up to the knee. The main components of cosmic rays are protons and helium nuclei, whereas the part of lepton component in the total flux is ~10E-3 for high energies. In present paper, the capability of the GAMMA-400 gamma-ray telescope to distinguish electrons and positrons from protons in cosmic rays is investigated. The individual contribution to the proton rejection is studied for each detector system of the GAMMA-400 gamma-ray telescope. Using combined information from all detector systems allow us to provide the proton rejection from electrons with a factor of ~4x10E5 for vertical incident particles and ~3x10E5 for particles with initial inclination of 30 degrees. The calculations were performed for the electron energy range from 50 GeV to 1 TeV., Comment: 19 pages, 10 figures, submitted to Advances and Space Research

Published
2015
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13. Study of the Gamma-ray performance of the GAMMA-400 Calorimeter

Author

Cumani, P., Galper, A. M., Bonvicini, V., Topchiev, N. P., Adriani, O., Aptekar, R. L., Argan, A., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bergstrom, L., Berti, E., Bigongiari, G., Bobkov, S. G., Boezio, M., Bogomolov, E. A., Bonechi, S., Bongi, M., Bottai, S., Bulgarelli, A., Castellini, G., Cattaneo, P. W., Dedenko, G. L., De Donato, C., Dogiel, V. A., Donnarumma, I., Fioretti, V., Gorbunov, M. S., Gusakov, Yu. V., Hnatyk, B. I., Kadilin, V. V., Kaplin, V. A., Kaplun, A. A., Kheymits, M. D., Korepanov, V. E., Larsson, J., Leonov, A. A., Loginov, V. A., Longo, F., Maestro, P., Marrocchesi, P. S., Menshenin, A. L., Mikhailov, V. V., Mocchiutti, E., Moiseev, A. A., Mori, N., Moskalenko, I. V., Naumov, P. Yu., Palma, F., Papini, P., Pearce, M., Piano, G., Picozza, P., Popov, A. V., Rappoldi, A., Ricciarini, S., Runtso, M. F., Ryde, F., Sabatini, S., Sarkar, R., Serdin, O. V., Sparvoli, R., Spillantini, P., Suchkov, S. I., Tavani, M., Taraskin, A. A., Tiberio, A., Tyurin, E. M., Ulanov, M. V., Vacchi, A., Vannuccini, E., Vasilyev, G. I., Vittorini, V., Yurkin, Yu. T., Zampa, N., Zirakashvili, V. N., and Zverev, V. G.

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - High Energy Astrophysical Phenomena
Abstract

GAMMA-400 is a new space mission, designed as a dual experiment, capable to study both high energy gamma rays (from $\sim$100 MeV to few TeV) and cosmic rays (electrons up to 20 TeV and nuclei up to $\sim$10$^{15}$ eV). The full simulation framework of GAMMA-400 is based on the Geant4 toolkit. The details of the gamma-ray reconstruction pipeline in the pre-shower and calorimeter will be outlined. The performance of GAMMA-400 (PSF, effective area) have been obtained using this framework. The most updated results on them will be shown., Comment: 2014 Fermi Symposium proceedings - eConf C14102.1

Published
2015

14. The GAMMA-400 Space Mission

Author

Cumani, P., Galper, A. M., Bonvicini, V., Topchiev, N. P., Adriani, O., Aptekar, R. L., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bergstrom, L., Berti, E., Bigongiari, G., Bobkov, S. G., Boezio, M., Bogomolov, E. A., Bonechi, S., Bongi, M., Bottai, S., Castellini, G., Cattaneo, P. W., Dedenko, G. L., De Donato, C., Dogiel, V. A., Gorbunov, M. S., Gusakov, Yu. V., Hnatyk, B. I., Kadilin, V. V., Kaplin, V. A., Kaplun, A. A., Kheymits, M. D., Korepanov, V. E., Larsson, J., Leonov, A. A., Loginov, V. A., Longo, F., Maestro, P., Marrocchesi, P. S., Menshenin, A. L., Mikhailov, V. V., Mocchiutti, E., Moiseev, A. A., Mori, N., Moskalenko, I. V., Naumov, P. Yu., Papini, P., Pearce, M., Picozza, P., Popov, A. V., Rappoldi, A., Ricciarini, S., Runtso, M. F., Ryde, F., Serdin, O. V., Sparvoli, R., Spillantini, P., Suchkov, S. I., Tavani, M., Taraskin, A. A., Tiberio, A., Tyurin, E. M., Ulanov, M. V., Vacchi, A., Vannuccini, E., Vasilyev, G. I., Yurkin, Yu. T., Zampa, N., Zirakashvili, V. N., and Zverev, V. G.

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - High Energy Astrophysical Phenomena
Abstract

GAMMA-400 is a new space mission which will be installed on board the Russian space platform Navigator. It is scheduled to be launched at the beginning of the next decade. GAMMA-400 is designed to study simultaneously gamma rays (up to 3 TeV) and cosmic rays (electrons and positrons from 1 GeV to 20 TeV, nuclei up to 10$^{15}$-10$^{16}$ eV). Being a dual-purpose mission, GAMMA-400 will be able to address some of the most impelling science topics, such as search for signatures of dark matter, cosmic-rays origin and propagation, and the nature of transients. GAMMA-400 will try to solve the unanswered questions on these topics by high-precision measurements of the Galactic and extragalactic gamma-ray sources, Galactic and extragalactic diffuse emission and the spectra of cosmic-ray electrons + positrons and nuclei, thanks to excellent energy and angular resolutions., Comment: 2014 Fermi Symposium proceedings - eConf C14102.1

Published
2015

15. The GAMMA-400 space observatory: status and perspectives

Author

Galper, A. M., Bonvicini, V., Topchiev, N. P., Adriani, O., Aptekar, R. L., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bergstrom, L., Berti, E., Bigongiari, G., Bobkov, S. G., Boezio, M., Bogomolov, E. A., Bonechi, S., Bongi, M., Bottai, S., Boyarchuk, K. A., Castellini, G., Cattaneo, P. W., Cumani, P., Dedenko, G. L., De Donato, C., Dogiel, V. A., Gorbunov, M. S., Gusakov, Yu. V., Hnatyk, B. I., Kadilin, V. V., Kaplin, V. A., Kaplun, A. A., Kheymits, M. D., Korepanov, V. E., Larsson, J., Leonov, A. A., Loginov, V. A., Longo, F., Maestro, P., Marrocchesi, P. S., Mikhailov, V. V., Mocchiutti, E., Moiseev, A. A., Mori, N., Moskalenko, I. V., Naumov, P. Yu., Papini, P., Pearce, M., Picozza, P., Popov, A. V., Rappoldi, A., Ricciarini, S., Runtso, M. F., Ryde, F., Serdin, O. V., Sparvoli, R., Spillantini, P., Suchkov, S. I., Tavani, M., Taraskin, A. A., Tiberio, A., Tyurin, E. M., Ulanov, M. V., Vacchi, A., Vannuccini, E., Vasilyev, G. I., Yurkin, Yu. T., Zampa, N., Zirakashvili, V. N., and Zverev, V. G.

Subjects
Physics - Instrumentation and Detectors, Astrophysics - High Energy Astrophysical Phenomena, Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

The present design of the new space observatory GAMMA-400 is presented in this paper. The instrument has been designed for the optimal detection of gamma rays in a broad energy range (from ~100 MeV up to 3 TeV), with excellent angular and energy resolution. The observatory will also allow precise and high statistic studies of the electron component in the cosmic rays up to the multi TeV region, as well as protons and nuclei spectra up to the knee region. The GAMMA-400 observatory will allow to address a broad range of science topics, like search for signatures of dark matter, studies of Galactic and extragalactic gamma-ray sources, Galactic and extragalactic diffuse emission, gamma-ray bursts and charged cosmic rays acceleration and diffusion mechanism up to the knee.

Published
2014

16. The GAMMA-400 gamma-ray telescope characteristics. Angular resolution and electrons/protons separation

Author

Leonov, A. A., Galper, A. M., Bonvicini, V., Topchiev, N. P., Adriani, O., Aptekar, R. L., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bergstrom, L., Berti, E., Bigongiari, G., Bobkov, S. G., Boezio, M., Bogomolov, E. A., Bonechi, S., Bongi, M., Bottai, S., Boyarchuk, K. A., Castellini, G., Cattaneo, P. W., Cumani, P., Dedenko, G. L., De Donato, C., Dogiel, V. A., Gorbunov, M. S., Gusakov, Yu. V., Hnatyk, B. I., Kadilin, V. V., Kaplin, V. A., Kaplun, A. A., Kheymits, M. D., Korepanov, V. E., Larsson, J., Loginov, V. A., Longo, F., Maestro, P., Marrocchesi, P. S., Mikhailov, V. V., Mocchiutti, E., Moiseev, A. A., Mori, N., Moskalenko, I. V., Naumov, P. Yu., Papini, P., Pearce, M., Picozza, P., Popov, A. V., Rappoldi, A., Ricciarini, S., Runtso, M. F., Ryde, F., Serdin, O. V., Sparvoli, R., Spillantini, P., Suchkov, S. I., Tavani, M., Taraskin, A. A., Tiberio, A., Tyurin, E. M., Ulanov, M. V., Vacchi, A., Vannuccini, E., Vasilyev, G. I., Yurkin, Yu. T., Zampa, N., Zirakashvili, V. N., and Zverev, V. G.

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

The measurements of gamma-ray fluxes and cosmic-ray electrons and positrons in the energy range from 100 MeV to several TeV, which will be implemented by the specially designed GAMMA-400 gamma-ray telescope, concern with the following broad range of science topics. Searching for signatures of dark matter, surveying the celestial sphere in order to study gamma-ray point and extended sources, measuring the energy spectra of Galactic and extragalactic diffuse gamma-ray emission, studying gamma-ray bursts and gamma-ray emission from the Sun, as well as high precision measuring spectra of high-energy electrons and positrons, protons and nuclei up to the knee. To clarify these scientific problems with the new experimental data the GAMMA-400 gamma-ray telescope possesses unique physical characteristics comparing with previous and present experiments. For gamma-ray energies more than 100 GeV GAMMA-400 provides the energy resolution of ~1% and angular resolution better than 0.02 deg. The methods developed to reconstruct the direction of incident gamma photon are presented in this paper, as well as, the capability of the GAMMA-400 gamma-ray telescope to distinguish electrons and positrons from protons in cosmic rays is investigated., Comment: 7 pages, 6 figures, submitted to Proceedings of Science

Published
2014

21. Capabilities of the GAMMA-400 gamma-ray telescope to detect electron + positron flux at TeV-energies from lateral directions

Author

Mikhailov, Vladimir, primary, Galper, A. M., additional, Topchiev, N. P., additional, Arkhangelskaja, I. V., additional, Arkhangelskiy, A. I., additional, Bakaldin, A. V., additional, Chernysheva, I. V., additional, Dalkarov, O. D., additional, Egorov, A. E., additional, Kheymits, M. D., additional, Korotkov, M. G., additional, Leonov, A., additional, Malinin, A., additional, Mayorov, A. G., additional, Mikhailova, A. V., additional, Minaev, P. Yu., additional, Pappe, N. Yu., additional, Suchkov, S. I., additional, and Yurkin, Yu. T., additional

Published
2023
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24. The GAMMA-400 experiment: Status and prospects

Author

Topchiev, N. P., Galper, A. M., Bonvicini, V., Adriani, O., Aptekar, R. L., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bergstrom, L., Berti, E., Bigongiari, G., Bobkov, S. G., Bogomolov, E. A., Boezio, M., Bongi, M., Bonechi, S., Bottai, S., Boyarchuk, K. A., Vacchi, A., Vannuccini, E., Vasilyev, G. I., Castellini, G., Cattaneo, P. W., Cumani, P., Dedenko, G. L., Dogiel, V. A., De Donato, C., Hnatyk, B. I., Gorbunov, M. S., Gusakov, Yu. V., Zampa, N., Zverev, V. G., Zirakashvili, V. N., Kadilin, V. V., Kaplin, V. A., Kaplun, A. A., Korepanov, V. E., Larsson, J., Leonov, A. A., Loginov, V. A., Longo, F., Maestro, P., Marrocchesi, P. S., Mikhailov, V. V., Mocchiutti, E., Moiseev, A. A., Mori, N., Moskalenko, I. V., Naumov, P. Yu., Papini, P., Picozza, P., Pearce, M., Popov, A. V., Ryde, F., Rappoldi, A., Ricciarini, S., Runtso, M. F., Serdin, O. V., Sparvoli, R., Spillantini, P., Suchkov, S. I., Tavani, M., Taraskin, A. A., Tiberio, A., Tyurin, E. M., Ulanov, M. V., Fuglesang, Ch., Kheymits, M. D., and Yurkin, Yu. T.

Published
2015
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25. Capabilities of the GAMMA-400 gamma-ray telescope for lateral aperture

Author

Mikhailova, A V, primary, Bakaldin, A V, additional, Chernysheva, I V, additional, Galper, A M, additional, Kheymits, M D, additional, Leonov, A A, additional, Mayorov, A.G., additional, Mikhailov, V V, additional, Minaev, P Yu, additional, Suchkov, S I, additional, Topchiev, N P, additional, and Yurkin, Yu T, additional

Published
2020
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26. Design of the readout electronics for the fast trigger and time of flight of the GAMMA-400 gamma-ray telescope

Author

Arkhangelskiy, A I, primary, Galper, A M, additional, Arkhangelskaja, I V, additional, Bakaldin, A V, additional, Chasovikov, E N, additional, Chernysheva, I V, additional, Dalkarov, O D, additional, Egorov, A E, additional, Gusakov, Yu V, additional, Kheymits, M D, additional, Leonov, A A, additional, Pappe, N Yu, additional, Runtso, M F, additional, Stozhkov, Yu I, additional, Suchkov, S I, additional, Topchiev, N P, additional, and Yurkin, Y T, additional

Published
2020
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27. New method of high-energy gamma ray direction reconstruction in multilayered converters

Author

Kheymits, M D, primary, Galper, A M, additional, Arkhangelskaya, I V, additional, Arkhangelskiy, A I, additional, Bakaldin, A V, additional, Gusakov, Yu V, additional, Dalkarov, O D, additional, Djivelikyan, E A, additional, Egorov, A E, additional, Leonov, A A, additional, Naumov, P Yu, additional, Pappe, N Yu, additional, Runtso, M F, additional, Stogkov, Yu I, additional, Suchkov, S I, additional, Topchiev, N P, additional, Yurkin, Yu T, additional, and Zverev, V G, additional

Published
2019
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28. The beam test of anticoincidence scintillation detector prototype with SiPM readout and perspectives of GRBs studies for space-based gamma-ray telescope GAMMA-400

Author

Arkhangelskiy, A I, primary, Galper, A M, additional, Arkhangelskaja, I V, additional, Bakaldin, A V, additional, Chasovikov, E N, additional, Chernysheva, I V, additional, Dalkarov, O D, additional, Egorov, A E, additional, Gusakov, Yu V, additional, Kheymits, M D, additional, Leonov, A A, additional, Pappe, N Yu, additional, Runtso, M F, additional, Stozhkov, Yu I, additional, Suchkov, S I, additional, Topchiev, N P, additional, and Yurkin, Y T, additional

Published
2019
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29. Space-based GAMMA-400 mission for direct gamma- and cosmic-ray observations

Author

Topchiev, N P, primary, Galper, A M, additional, Arkhangelskaja, I V, additional, Arkhangelskiy, A I, additional, Bakaldin, A V, additional, Chernysheva, I V, additional, Dalkarov, O D, additional, Egorov, A E, additional, Gusakov, Yu V, additional, Kheymits, M D, additional, Leonov, A A, additional, Yu Naumov, P, additional, Yu Pappe, N, additional, Runtso, M F, additional, Stozhkov, Yu I, additional, Suchkov, S I, additional, Yurkin, Yu T, additional, and Zverev, V G, additional

Published
2019
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30. Separation of electrons and protons in the GAMMA-400 gamma-ray telescope

Author

Leonov, A. A., Galper, A. M., Bonvicini, V., Topchiev, N. P., Adriani, O., Aptekar, R. L., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bergstrom, L., Berti, E., Bigongiari, G., Bobkov, S. G., Boezio, M., Bogomolov, E. A., Bonechi, S., Bongi, M., Bottai, S., Castellini, G., Cattaneo, P. W., Cumani, P., Dedenko, G. L., De Donato, C., Dogiel, V. A., Gorbunov, M. S., Gusakov, Yu. V., Hnatyk, B. I., Kadilin, V. V., Kaplin, V. A., Kaplun, A. A., Kheymits, M. D., Korepanov, V. E., Larsson, J., Loginov, V. A., Longo, F., Maestro, P., Marrocchesi, P. S., Mikhailov, V. V., Mocchiutti, E., Moiseev, A. A., Mori, N., Moskalenko, I. V., Naumov, P. Yu., Papini, P., Pearce, M., Picozza, P., Popov, A. V., Rappoldi, A., Ricciarini, S., Runtso, M. F., Ryde, F., Serdin, O. V., Sparvoli, R., Spillantini, P., Suchkov, S. I., Tavani, M., Taraskin, A. A., Tiberio, A., Tyurin, E. M., Ulanov, M. V., Vacchi, A., Vannuccini, E., Vasilyev, G. I., Yurkin, Yu. T., Zampa, N., Zirakashvili, V. N., Zverev, V. G., Leonov, A. A, Galper, A. M., Bonvicini, V., Topchiev, N. P., Adriaini, O., Aptekar, R. L., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bergstrom, L., Berti, E., Bigongiari, G., Bobkov, S. G., Boezio, M., Bogomolov, E. A., Bonechi, S., Bongi, M., Bottai, S., Castellini, G., Cattaneo, P. W., Cumani, Paolo, Dedenko, G. L., De Donato, C., Dogiel, V. A., Gorbunov, M. S., Gusakov, Y. u. V., Hnatyk, B. I., Kadilin, V. V., Kaplin, V. A., Kaplun, A. A., Kheymits, M. D., Korepanov, V. E., Larsson, J., Loginov, V. A., Longo, Francesco, Maestro, P., Marrocchesi, P. S., Mikhailov, V. V., Mocchiutti, E., Moiseev, A. A., Mori, N., Moskalenko, I. V., Naumov, P. Y. u., Papini, P., Pearce, M., Picozza, P., Rappoldi, A., Ricciarini, S., Runtso, M. F., Ryde, F., Serdin, O. V., Sparvoli, R., Spillantini, P., Suchkov, S. I., Taraskin, A. A., Tavani, M., Tiberio, A., Tyurin, E. M., Ulanov, M. V., Vacchi, A., Vannuccini, E., Vasilyev, G. I., Yurkin, Y. u. T., Zampa, N., Zirakashvili, V. N., and Zverev, V. G.

Subjects
Space experiments, Atmospheric Science, Physics - Instrumentation and Detectors, Hadron and electromagnetic shower, Astrophysics::High Energy Astrophysical Phenomena, Gamma ray, FOS: Physical sciences, Aerospace Engineering, Cosmic ray, Astrophysics::Cosmology and Extragalactic Astrophysics, Astrophysics, Electron, law.invention, Telescope, Positron, law, Instrumentation and Methods for Astrophysics (astro-ph.IM), Cosmic rays, Physics, Range (particle radiation), Settore FIS/04, Gamma rays, Astrophysics::Instrumentation and Methods for Astrophysics, Astronomy and Astrophysics, Instrumentation and Detectors (physics.ins-det), Space experiment, Hadron and electromagnetic showers, Geophysics, Space and Planetary Science, Gamma-ray telescope, General Earth and Planetary Sciences, Physics::Accelerator Physics, High Energy Physics::Experiment, Astrophysics - Instrumentation and Methods for Astrophysics, Fermi Gamma-ray Space Telescope
Abstract

The GAMMA-400 gamma-ray telescope is intended to measure the fluxes of gamma rays and cosmic-ray electrons and positrons in the energy range from 100 MeV to several TeV. Such measurements concern with the following scientific goals: search for signatures of dark matter, investigation of gamma-ray point and extended sources, studies of the energy spectra of Galactic and extragalactic diffuse emission, studies of gamma-ray bursts and gamma-ray emission from the active Sun, as well as high-precision measurements of spectra of high-energy electrons and positrons, protons, and nuclei up to the knee. The main components of cosmic rays are protons and helium nuclei, whereas the part of lepton component in the total flux is ~10E-3 for high energies. In present paper, the capability of the GAMMA-400 gamma-ray telescope to distinguish electrons and positrons from protons in cosmic rays is investigated. The individual contribution to the proton rejection is studied for each detector system of the GAMMA-400 gamma-ray telescope. Using combined information from all detector systems allow us to provide the proton rejection from electrons with a factor of ~4x10E5 for vertical incident particles and ~3x10E5 for particles with initial inclination of 30 degrees. The calculations were performed for the electron energy range from 50 GeV to 1 TeV., Comment: 19 pages, 10 figures, submitted to Advances and Space Research

Published
2015
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32. Modifications of a method for low energy gamma-ray incident angle reconstruction in the GAMMA-400 gamma-ray telescope

Author

Leonov, A A, primary, Galper, A M, additional, Topchiev, N P, additional, Bonvicini, V, additional, Adriani, O, additional, Arkhangelskaja, I V, additional, Arkhangelskiy, A I, additional, Bakaldin, A V, additional, Bobkov, S G, additional, Boezio, M, additional, Dalkarov, O D, additional, Egorov, A E, additional, Glushkov, N A, additional, Gorbunov, M S, additional, Gusakov, Yu V, additional, Hnatyk, B I, additional, Kadilin, V V, additional, Kaplin, V A, additional, Kheymits, M D, additional, Korepanov, V E, additional, Longo, F, additional, Mikhailov, V V, additional, Mocchiutti, E, additional, Moiseev, A A, additional, Moskalenko, I V, additional, Naumov, P Yu, additional, Picozza, P, additional, Runtso, M F, additional, Serdin, O V, additional, Sparvoli, R, additional, Spillantini, P, additional, Stozhkov, Yu I, additional, Suchkov, S I, additional, Taraskin, A A, additional, Tavani, M, additional, Yurkin, Yu T, additional, and Zverev, V G, additional

Published
2017
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33. High-energy gamma-ray studying with GAMMA-400 after Fermi-LAT

Author

Topchiev, N P, primary, Galper, A M, additional, Bonvicini, V, additional, Adriani, O, additional, Arkhangelskaja, I V, additional, Arkhangelskiy, A I, additional, Bakaldin, A V, additional, Bobkov, S G, additional, Boezio, M, additional, Dalkarov, O D, additional, Egorov, A E, additional, Gorbunov, M S, additional, Gusakov, Yu V, additional, Hnatyk, B I, additional, Kadilin, V V, additional, Kaplin, V A, additional, Kheymits, M D, additional, Korepanov, V E, additional, Leonov, A A, additional, Longo, F, additional, Mikhailov, V V, additional, Mocchiutti, E, additional, Moiseev, A A, additional, Moskalenko, I V, additional, Naumov, P Yu, additional, Picozza, P, additional, Runtso, M F, additional, Serdin, O V, additional, Sparvoli, R, additional, Spillantini, P, additional, Stozhkov, Yu I, additional, Suchkov, S I, additional, Taraskin, A A, additional, Tavani, M, additional, Yurkin, Yu T, additional, and Zverev, V G, additional

Published
2017
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35. The high energy cosmic ray particle spectra measurements with the PAMELA calorimeter

Author

Karelin, A. V., Adriani, O., Barbarino, G. C., Bazilevskaya, G. A., Bellotti, R., Boezio, M., Bogomolov, E. A., Bongi, M., Bonvicini, V., Bottai, S., Bruno, A., Cafagna, F., Carbone, R., Carlson, Per, Casolino, M., Castellini, G., De Pascale, M. P., De Santis, C., De Simone, N., Di Felice, V., Formato, V., Galper, A. M., Kheymits, M. D., Giaccari, U., Koldashov, S. V., Koldobskiy, S., Krutkov, S., Kvashnin, A. N., Leonov, A., Malakhov, V., Marcelli, L., Martucci, M., Mayorov, A. G., Menn, W., Merge, M., Mikhailov, V. V., Mocchiutti, E., Monaco, A., Mori, N., Munini, Riccardo, Osteria, G., Papini, P., Pearce, Mark, Picozza, P., Ricci, M., Ricciarini, S. B., Rossetto, Laura, Sarkar, R., Simon, M., Sparvoli, R., Spillantini, P., Vacchi, A., Vannuccini, E., Vasilyev, G. I., Voronov, S. A., Yurkin, Y. T., Zampa, G., Zampa, N., Zverev, V. G., Karelin, A. V., Adriani, O., Barbarino, G. C., Bazilevskaya, G. A., Bellotti, R., Boezio, M., Bogomolov, E. A., Bongi, M., Bonvicini, V., Bottai, S., Bruno, A., Cafagna, F., Carbone, R., Carlson, Per, Casolino, M., Castellini, G., De Pascale, M. P., De Santis, C., De Simone, N., Di Felice, V., Formato, V., Galper, A. M., Kheymits, M. D., Giaccari, U., Koldashov, S. V., Koldobskiy, S., Krutkov, S., Kvashnin, A. N., Leonov, A., Malakhov, V., Marcelli, L., Martucci, M., Mayorov, A. G., Menn, W., Merge, M., Mikhailov, V. V., Mocchiutti, E., Monaco, A., Mori, N., Munini, Riccardo, Osteria, G., Papini, P., Pearce, Mark, Picozza, P., Ricci, M., Ricciarini, S. B., Rossetto, Laura, Sarkar, R., Simon, M., Sparvoli, R., Spillantini, P., Vacchi, A., Vannuccini, E., Vasilyev, G. I., Voronov, S. A., Yurkin, Y. T., Zampa, G., Zampa, N., and Zverev, V. G.

Abstract

Up until now there has been limited, contradictive data on the high energy range of the cosmic ray electron-positron, proton and helium spectra. Due to the limitations of the use of a magnetic spectrometer, over 8 years experimental data was processed using information from a sampling electro-magnetic calorimeter, a neutron detector and scintillator detectors. The use of these devices allowed us to successfully obtain the high energy cosmic ray particle spectra measurements. The results of this study clarify previous findings and greaten our understanding of the origin of cosmic rays., QC 20161115

Published
2016
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37. Perspectives of the GAMMA-400 space observatory for high-energy gamma rays and cosmic rays measurements

Author

Topchiev, N P, primary, Galper, A M, additional, Bonvicini, V, additional, Adriani, O, additional, Aptekar, R L, additional, Arkhangelskaja, I V, additional, Arkhangelskiy, A I, additional, Bakaldin, A V, additional, Bergstrom, L, additional, Berti, E, additional, Bigongiari, G, additional, Bobkov, S G, additional, Boezio, M, additional, Bogomolov, E A, additional, Bonechi, S, additional, Bongi, M, additional, Bottai, S, additional, Castellini, G, additional, Cattaneo, P W, additional, Cumani, P, additional, Dalkarov, O D, additional, Dedenko, G L, additional, De Donato, C, additional, Dogiel, V A, additional, Finetti, N, additional, Gorbunov, M S, additional, Gusakov, Yu V, additional, Hnatyk, B I, additional, Kadilin, V V, additional, Kaplin, V A, additional, Kaplun, A A, additional, Kheymits, M D, additional, Korepanov, V E, additional, Larsson, J, additional, Leonov, A A, additional, Loginov, V A, additional, Longo, F, additional, Maestro, P, additional, Marrocchesi, P S, additional, Men'shenin, A L, additional, Mikhailov, V V, additional, Mocchiutti, E, additional, Moiseev, A A, additional, Mori, N, additional, Moskalenko, I V, additional, Naumov, P Yu, additional, Papini, P, additional, Pearce, M, additional, Picozza, P, additional, Rappoldi, A, additional, Ricciarini, S, additional, Runtso, M F, additional, Ryde, F, additional, Serdin, O V, additional, Sparvoli, R, additional, Spillantini, P, additional, Stozhkov, Yu I, additional, Suchkov, S I, additional, Taraskin, A A, additional, Tavani, M, additional, Tiberio, A, additional, Tyurin, E M, additional, Ulanov, M V, additional, Vacchi, A, additional, Vannuccini, E, additional, Vasilyev, G I, additional, Yurkin, Yu T, additional, Zampa, N, additional, Zirakashvili, V N, additional, and Zverev, V G, additional

Published
2016
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39. The GAMMA-400 gamma-ray telescope for precision gamma-ray emission investigations

Author

Topchiev, N P, primary, Galper, A M, additional, Bonvicini, V, additional, Adriani, O, additional, Aptekar, R L, additional, Arkhangelskaja, I V, additional, Arkhangelskiy, A I, additional, Bakaldin, A V, additional, Bergstrom, L, additional, Berti, E, additional, Bigongiari, G, additional, Bobkov, S G, additional, Boezio, M, additional, Bogomolov, E A, additional, Bonechi, L, additional, Bongi, M, additional, Bottai, S, additional, Castellini, G, additional, Cattaneo, P W, additional, Cumani, P, additional, Dalkarov, O D, additional, Dedenko, G L, additional, De Donato, C, additional, Dogiel, V A, additional, Finetti, N, additional, Gascon, D, additional, Gorbunov, M S, additional, Gusakov, Yu V, additional, Hnatyk, B I, additional, Kadilin, V V, additional, Kaplin, V A, additional, Kaplun, A A, additional, Kheymits, M D, additional, Korepanov, V E, additional, Larsson, J, additional, Leonov, A A, additional, Loginov, V A, additional, Longo, F, additional, Maestro, P, additional, Marrocchesi, P S, additional, Martinez, M, additional, Men'shenin, A L, additional, Mikhailov, V V, additional, Mocchiutti, E, additional, Moiseev, A A, additional, Mori, N, additional, Moskalenko, I V, additional, Naumov, P Yu, additional, Papini, P, additional, Paredes, J M, additional, Pearce, M, additional, Picozza, P, additional, Rappoldi, A, additional, Ricciarini, S, additional, Runtso, M F, additional, Ryde, F, additional, Serdin, O V, additional, Sparvoli, R, additional, Spillantini, P, additional, Stozhkov, Yu I, additional, Suchkov, S I, additional, Taraskin, A A, additional, Tavani, M, additional, Tiberio, A, additional, Tyurin, E M, additional, Ulanov, M V, additional, Vacchi, A, additional, Vannuccini, E, additional, Vasilyev, G I, additional, Ward, J E, additional, Yurkin, Yu T, additional, Zampa, N, additional, Zirakashvili, V N, additional, and Zverev, V G, additional

Published
2016
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40. Method to select gamma rays with energy above 50 GeV against a charge-particle background in the GAMMA-400 space telescope

Author

Kheymits, M D, primary, Leonov, A A, additional, Galper, A M, additional, Kadilin, V, additional, Arkhangelskaya, I V, additional, Arkhangelskiy, A I, additional, Gusakov, Yu V, additional, Zverev, V G, additional, Kaplin, V, additional, Naumov, P Yu, additional, Runtso, M F, additional, Suchkov, S I, additional, Topchiev, N P, additional, Yurkin, Yu T, additional, Bakaldin, A, additional, and Dalkarov, O, additional

Published
2016
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42. New stage in high-energy gamma-ray studies with GAMMA-400 after Fermi-LAT.

Author

Topchiev, N. P., Galper, A. M., Bonvicini, V., Adriani, O., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bakaldin, A. V., Bobkov, S. G., Boezio, M., Dalkarov, O. D., Egorov, A. E., Gorbunov, M. S., Gusakov, Yu. V., Hnatyk, B. I., Kadilin, V. V., Kaplin, V. A., Kheymits, M. D., Korepanov, V. E., Leonov, A. A., and Longo, F.

Subjects
GAMMA rays, DARK matter, GALACTIC center, FERMI energy, EXTRAGALACTIC distances
Abstract

Fermi-LAT has made a significant contribution to the study of high-energy gamma-ray diffuse emission and the observations of 3000 discrete sources. However, one third of all gamma-ray sources (both galactic and extragalactic) are unidentified, the data on the diffuse gamma-ray emission should be clarified, and signatures of dark matter particles in the high-energy gamma-ray range are not observed up to now. GAMMA-400, the currently developing gamma-ray telescope, will have angular (~0.01° at 100 GeV) and energy (~1% at 100 GeV) resolutions in the energy range of 10-1000 GeV which are better than Fermi-LAT (as well as ground gamma-ray telescopes) by a factor of 5-10. It will observe some regions of the Universe (such as the Galactic Center, Fermi Bubbles, Crab, Cygnus, etc.) in a highly elliptic orbit (without shading the telescope by the Earth) continuously for a long time. It will allow us to identify many discrete sources, to clarify the structure of extended sources, to specify the data on the diffuse emission, and to resolve gamma rays from dark matter particles. [ABSTRACT FROM AUTHOR]

Published
2017
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43. High-energy gamma-ray studying with GAMMA-400 after Fermi-LAT

Author

S. I. Suchkov, V. G. Zverev, Yu. I. Stozhkov, Yu. T. Yurkin, A. E. Egorov, V. V. Kadilin, Alexey Leonov, I. V. Arkhangelskaja, Valery Korepanov, Maxim S. Gorbunov, E. Mocchiutti, A. A. Moiseev, A. M. Galper, Marco Tavani, A. A. Taraskin, M. F. Runtso, Igor V. Moskalenko, V. V. Mikhailov, A.I. Arkhangelskiy, O. D. Dalkarov, M. D. Kheymits, P. Picozza, O. V. Serdin, A. V. Bakaldin, O. Adriani, P. Yu. Naumov, V. Bonvicini, Vladimir Kaplin, Yu. V. Gusakov, N. P. Topchiev, S G Bobkov, Piero Spillantini, Mirko Boezio, Bohdan Hnatyk, Francesco Longo, Roberta Sparvoli, M. Strikhanov, O. Nagornov, S. Rubin, Topchiev, N. P., Galper, A. M., Bonvicini, V., Adriani, O., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bakaldin, A. V., Bobkov, S. G., Boezio, M., Dalkarov, O. D., Egorov, A. E., Gorbunov, M. S., Gusakov, Yu. V., Hnatyk, B. I., Kadilin, V. V., Kaplin, V. A., Kheymits, M. D., Korepanov, V. E., Leonov, A. A., Longo, F., Mikhailov, V. V., Mocchiutti, E., Moiseev, A. A., Moskalenko, I. V., Naumov, P. Y., Picozza, P., Runtso, M. F., Serdin, O. V., Sparvoli, R., Spillantini, P., Stozhkov, Y. I., Suchkov, S. I., Taraskin, A. A., Tavani, M., Yurkin, Y. T., and Zverev, V. G.

Subjects
History, High energy, Elliptic orbit, 010504 meteorology & atmospheric sciences, gamma-ray astrophysics, gamma-ray telescopes, Astrophysics::High Energy Astrophysical Phenomena, Dark matter, gamma-ray astrophysic, Astrophysics::Cosmology and Extragalactic Astrophysics, Astrophysics, 01 natural sciences, Education, law.invention, Telescope, law, 0103 physical sciences, Gamma ray, Gamma400, 010303 astronomy & astrophysics, Astrophysics::Galaxy Astrophysics, 0105 earth and related environmental sciences, Physics, Settore FIS/01, Range (particle radiation), Galactic Center, Gamma ray, Computer Science Applications, Fermi Gamma-ray Space Telescope
Abstract

Fermi-LAT has made a significant contribution to the study of high-energy gamma-ray diffuse emission and the observation of ~3000 discrete sources. However, one third of all gamma-ray sources (both galactic and extragalactic) are unidentified, the data on the diffuse gamma-ray emission should be clarified, and signatures of dark matter particles in the high-energy gamma-ray range are not observed up to now. GAMMA-400, currently developing gamma-ray telescope, will have the angular (~0.01° at 100 GeV) and energy (~1% at 100 GeV) resolutions in the energy range of 10-1000 GeV better than the Fermi-LAT (as well as ground gamma-ray telescopes) by a factor of 5-10 and observe some regions of the Universe (such as Galactic Center, Fermi Bubbles, Crab, Cygnus, etc.) in the highly elliptic orbit (without shading the telescope by the Earth) continuously for a long time. It will permit to identify many discrete sources, to clarify the structure of extended sources, to specify the data on the diffuse emission, and to resolve gamma rays from dark matter particles.

Published
2017

44. New stage in high-energy gamma-ray studies with GAMMA-400 after Fermi-LAT

Author

Piero Spillantini, A. I. Arkhangelskiy, V. V. Kadilin, S. G. Bobkov, A. E. Egorov, S. I. Suchkov, O. Adriani, Igor V. Moskalenko, Alexander Moiseev, Yu. I. Stozhkov, P. Yu. Naumov, Vladimir Kaplin, V. Bonvicini, E. Mocchiutti, Marco Tavani, P. Picozza, Maxim S. Gorbunov, A. A. Taraskin, I. V. Arkhangelskaja, N. P. Topchiev, V.G. Zverev, O. V. Serdin, Mirko Boezio, A. V. Bakaldin, A. M. Galper, Yu. V. Gusakov, V. V. Mikhailov, Bohdan Hnatyk, Valery Korepanov, Francesco Longo, Roberta Sparvoli, Alexey Leonov, M. F. Runtso, O. D. Dalkarov, M. D. Kheymits, Yu. T. Yurkin, Nicolay Kolachevsky, Oleg Dalkarov, Topchiev, N. P., Galper, A. M., Bonvicini, V., Adriani, O., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bakaldin, A. V., Bobkov, S. G., Boezio, M., Dalkarov, O. D., Egorov, A. E., Gorbunov, M. S., Gusakov, Yu. V., Hnatyk, B. I., Kadilin, V. V., Kaplin, V. A., Kheymits, M. D., Korepanov, V. E., Leonov, A. A., Longo, F., Mikhailov, V. V., Mocchiutti, E., Moiseev, A. A., Moskalenko, I. V., Naumov, P. Yu., Picozza, P., Runtso, M. F., Serdin, O. V., Sparvoli, R., Spillantini, P., Stozhkov, Yu. I., Suchkov, S. I., Taraskin, A. A., Tavani, M., Yurkin, Yu. T., and Zverev, V. G.

Subjects
Elliptic orbit, gamma-ray satellites, Astrophysics::High Energy Astrophysical Phenomena, QC1-999, gamma-ray astrophysic, Dark matter, 02 engineering and technology, Astrophysics, Astrophysics::Cosmology and Extragalactic Astrophysics, 01 natural sciences, law.invention, Telescope, law, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, 010303 astronomy & astrophysics, Astrophysics::Galaxy Astrophysics, Physics, Settore FIS/01, Gamma Ray, GAMMA400, Range (particle radiation), Galactic Center, Gamma ray, 020206 networking & telecommunications, gamma-ray astrophysics, Stage (hydrology), Fermi Gamma-ray Space Telescope
Abstract

Fermi-LAT has made a significant contribution to the study of high-energy gamma-ray diffuse emission and the observations of 3000 discrete sources. However, one third of all gamma-ray sources (both galactic and extragalactic) are unidentified, the data on the diffuse gamma-ray emission should be clarified, and signatures of dark matter particles in the high-energy gamma-ray range are not observed up to now. GAMMA-400, the currently developing gamma-ray telescope, will have angular (∼0.01∘ at 100 GeV) and energy (∼1% at 100 GeV) resolutions in the energy range of 10–1000 GeV which are better than Fermi-LAT (as well as ground gamma-ray telescopes) by a factor of 5–10. It will observe some regions of the Universe (such as the Galactic Center, Fermi Bubbles, Crab, Cygnus, etc.) in a highly elliptic orbit (without shading the telescope by the Earth) continuously for a long time. It will allow us to identify many discrete sources, to clarify the structure of extended sources, to specify the data on the diffuse emission, and to resolve gamma rays from dark matter particles.

Published
2017

45. Perspectives of the GAMMA-400 space observatory for high-energy gamma rays and cosmic rays measurements

Author

A. L. Menshenin, G. Castellini, M. F. Runtso, S G Bobkov, Valery Korepanov, N P Topchiev, O. D. Dalkarov, Yu. I. Stozhkov, A. A. Moiseev, R. L. Aptekar, G Bigongiari, Francesco Longo, N Finetti, C. De Donato, A. Vacchi, A Tiberio, P.W. Cattaneo, P S Marrocchesi, P. Yu. Naumov, V. V. Mikhailov, A. V. Bakaldin, Roberta Sparvoli, N. Zampa, Vladimir Kaplin, A. M. Galper, Igor V. Moskalenko, Nicola Mori, Yu. T. Yurkin, E. M. Tyurin, P. Picozza, S. Bonechi, Felix Ryde, Paolo Maestro, M. Ulanov, V. V. Kadilin, Mark Pearce, E. Vannuccini, Piero Spillantini, Maxim S. Gorbunov, O. V. Serdin, Josefin Larsson, P. Papini, Marco Tavani, A. Rappoldi, Mirko Boezio, A. A. Taraskin, S. B. Ricciarini, S. I. Suchkov, V. N. Zirakashvili, I. V. Arkhangelskaja, V. A. Loginov, O. Adriani, G. L. Dedenko, G. I. Vasilyev, Bohdan Hnatyk, V. G. Zverev, A. A. Kaplun, E. A. Bogomolov, Yu. V. Gusakov, E Berti, A.I. Arkhangelskiy, M. D. Kheymits, M. Bongi, E. Mocchiutti, P. Cumani, Alexey Leonov, V. Bonvicini, V. A. Dogiel, L. Bergstrom, S. Bottai, S. Rubin, A. Galper, A. Petrukhin, M. Skorokhvatov, Topchiev, N. P., Galper, A. M., Bonvicini, V., Adriani, O., Aptekar, R. L., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bakaldin, A. V., Bergstrom, L., Berti, E., Bigongiari, G., Bobkov, S. G., Boezio, M., Bogomolov, E. A., Bonechi, S., Bongi, M., Bottai, S., Castellini, G., Cattaneo, P. W., Cumani, P., Dalkarov, O. D., Dedenko, G. L., De Donato, C., Dogiel, V. A., Finetti, N., Gorbunov, M. S., Gusakov, Y. V., Hnatyk, B. I., Kadilin, V. V., Kaplin, V. A., Kaplun, A. A., Kheymits, M. D., Korepanov, V. E., Larsson, J., Leonov, A. A., Loginov, V. A., Longo, F., Maestro, P., Marrocchesi, P. S., Men'Shenin, A. L., Mikhailov, V. V., Mocchiutti, E., Moiseev, A. A., Mori, N., Moskalenko, I. V., Naumov, P. Y., Papini, P., Pearce, M., Picozza, P., Rappoldi, A., Ricciarini, S., Runtso, M. F., Ryde, F., Serdin, O. V., Sparvoli, R., Spillantini, P., Stozhkov, Y. I., Suchkov, S. I., Taraskin, A. A., Tavani, M., Tiberio, A., Tyurin, E. M., Ulanov, M. V., Vacchi, A., Vannuccini, E., Vasilyev, G. I., Yurkin, Y. T., Zampa, N., Zirakashvili, V. N., and Zverev, V. G.

Subjects
History, 010504 meteorology & atmospheric sciences, Astrophysics::High Energy Astrophysical Phenomena, Dark matter, Highly elliptical orbit, cosmic-rays, Cosmic ray, Astrophysics, 01 natural sciences, Education, law.invention, Telescope, Physics and Astronomy (all), law, 0103 physical sciences, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Physics, Settore FIS/04, Gamma ray, Astrophysics::Instrumentation and Methods for Astrophysics, Astronomy, gamma-ray telescopes, Gamma-ray astronomy, Orbital period, gamma-ray telescope, Computer Science Applications, Cosmic ray measurement, Cosmic rays, Cosmology, Positrons, Space platforms, Telescopes, Tellurium compounds, Fermi Gamma-ray Space Telescope
Abstract

The GAMMA-400 gamma-ray telescope is intended to measure the fluxes of gamma-rays and cosmic-ray electrons and positrons in the energy range from 100 MeV to several TeV. Such measurements concern the following scientific tasks: investigation of point sources of gamma-rays, studies of the energy spectra of Galactic and extragalactic diffuse emission, studies of gamma-ray bursts and gamma-ray emission from the Sun, as well as high precision measurements of spectra of high-energy electrons and positrons. Also the GAMMA- 400 instrument provides the possibility for protons and nuclei measurements up to knee. But the main goal for the GAMMA-400 mission is to perform a sensitive search for signatures of dark matter particles in high-energy gamma-ray emission. To fulfill these measurements the GAMMA-400 gamma-ray telescope possesses unique physical characteristics in comparison with previous and present experiments. The major advantage of the GAMMA-400 instrument is excellent angular and energy resolution for gamma-rays above 10 GeV. The GAMMA-400 experiment will be installed onboard of the Navigator space platform, manufactured by the NPO Lavochkin Association. The expected orbit will be a highly elliptical orbit (with apogee 300.000 km and perigee 500 km) with 7 days orbital period. An important profit of such an orbit is the fact that the full sky coverage will always be available for gamma ray astronomy.

Published
2016

46. The GAMMA-400 gamma-ray telescope for precision gamma-ray emission investigations

Author

P. Yu. Naumov, Vladimir Kaplin, S. G. Bobkov, G. L. Dedenko, O. V. Serdin, Miriam Lucio Martinez, Lorenzo Bonechi, A.I. Arkhangelskiy, Igor V. Moskalenko, Bohdan Hnatyk, Piero Spillantini, R. Aptekar, V. G. Zverev, Josefin Larsson, Marco Tavani, A. Rappoldi, Yu. T. Yurkin, V. A. Dogiel, M. F. Runtso, Mirko Boezio, Francesco Longo, E. A. Bogomolov, O. Adriani, Mark Pearce, S. B. Ricciarini, Roberta Sparvoli, A. V. Bakaldin, Alexey Leonov, G Bigongiari, J. E. Ward, David Gascon, S. Bottai, M. Bongi, A. A. Moiseev, E. Mocchiutti, P. Cumani, Paolo Maestro, Nikolay Topchiev, Yu. I. Stozhkov, N Finetti, V. N. Zirakashvili, M. D. Kheymits, P S Marrocchesi, A. M. Galper, C. De Donato, Y. u. V. Gusakov, O.D. Dalkarov, V. V. Mikhailov, A Tiberio, Felix Ryde, V. Bonvicini, J. M. Paredes, P. Picozza, G. Castellini, Valery Korepanov, L. Bergstrom, N. Zampa, P. Papini, A. L. Menshenin, S. I. Suchkov, Nicola Mori, M. Ulanov, E Berti, V. V. Kadilin, G. I. Vasilyev, E. Vannuccini, A. A. Kaplun, P.W. Cattaneo, I. V. Arkhangelskaja, A. Vacchi, E. M. Tyurin, Maxim S. Gorbunov, A. A. Taraskin, V. A. Loginov, S. Rubin, A. Galper, A. Petrukhin, M. Skorokhvatov, Topchiev, N. P., Galper, A. M., Bonvicini, V., Adriani, O., Aptekar, R. L., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bakaldin, A. V., Bergstrom, L., Berti, E., Bigongiari, G., Bobkov, S. G., Boezio, M., Bogomolov, E. A., Bonechi, L., Bongi, M., Bottai, S., Castellini, G., Cattaneo, P. W., Cumani, P., Dalkarov, O. D., Dedenko, G. L., De Donato, C., Dogiel, V. A., Finetti, N., Gascon, D., Gorbunov, M. S., Gusakov, Y. V., Hnatyk, B. I., Kadilin, V. V., Kaplin, V. A., Kaplun, A. A., Kheymits, M. D., Korepanov, V. E., Larsson, J., Leonov, A. A., Loginov, V. A., Longo, F., Maestro, P., Marrocchesi, P. S., Martinez, M., Men'Shenin, A. L., Mikhailov, V. V., Mocchiutti, E., Moiseev, A. A., Mori, N., Moskalenko, I. V., Naumov, P. Y., Papini, P., Paredes, J. M., Pearce, M., Picozza, P., Rappoldi, A., Ricciarini, S., Runtso, M. F., Ryde, F., Serdin, O. V., Sparvoli, R., Spillantini, P., Stozhkov, Y. I., Suchkov, S. I., Taraskin, A. A., Tavani, M., Tiberio, A., Tyurin, E. M., Ulanov, M. V., Vacchi, A., Vannuccini, E., Vasilyev, G. I., Ward, J. E., Yurkin, Y. T., Zampa, N., Zirakashvili, V. N., and Zverev, V. G.

Subjects
History, Astrophysics::High Energy Astrophysical Phenomena, Dark matter, Astrophysics::Cosmology and Extragalactic Astrophysics, Electron, Astrophysics, 01 natural sciences, gamma-ray source, dark matter, Education, law.invention, Telescope, Physics and Astronomy (all), Positron, law, 0103 physical sciences, 010303 astronomy & astrophysics, Cosmic rays, Cosmology, Electrons, Positrons, Solar energy, Telescopes, Tellurium compounds, gamma-ray sources, Astrophysics::Galaxy Astrophysics, Physics, gamma-ray telescopes, 010308 nuclear & particles physics, Settore FIS/04, Gamma rays, Gamma ray, Astronomy, gamma-ray telescope, Computer Science Applications, Physics::Accelerator Physics, Fermi Gamma-ray Space Telescope
Abstract

The GAMMA-400 gamma-ray telescope with excellent angular and energy resolutions is designed to search for signatures of dark matter in the fluxes of gamma-ray emission and electrons + positrons. Precision investigations of gamma-ray emission from Galactic Center, Crab, Vela, Cygnus, Geminga, and other regions will be performed, as well as diffuse gamma-ray emission, along with measurements of high-energy electron + positron and nuclei fluxes. Furthermore, it will study gamma-ray bursts and gamma-ray emission from the Sun during periods of solar activity. The GAMMA-400 energy range is expected to be from ~20 MeV up to TeV energies for gamma rays, up to 10 TeV for electrons + positrons, and up to 1015 eV for cosmic-ray nuclei. For 100-GeV gamma rays, the GAMMA-400 angular resolution is ~0.01° and energy resolution is ~1%; the proton rejection factor is ~5x105. GAMMA-400 will be installed onboard the Russian space observatory.[object Object]

Published
2016

47. The GAMMA-400 experiment: Status and prospects

Author

A. M. Galper, Yu. T. Yurkin, O. V. Serdin, P. Spillantini, S. Bonechi, A. A. Kaplun, Josefin Larsson, Marco Tavani, C. Fuglesang, Felix Ryde, R. L. Aptekar, G. I. Vasilyev, A. V. Popov, G. Castellini, Igor V. Moskalenko, Maxim S. Gorbunov, Francesco Longo, S. Bottai, V. V. Kadilin, Gabriele Bigongiari, K. A. Boyarchuk, A. A. Taraskin, Nicola Mori, Eugenio Berti, A. Tiberio, M. F. Runtso, Roberta Sparvoli, Mirko Boezio, M. D. Kheymits, Valery Korepanov, A. A. Moiseev, E. A. Bogomolov, M. Bongi, P. Yu. Naumov, V. A. Loginov, C. De Donato, Vladimir Kaplin, Alexey Leonov, V. V. Mikhailov, P. Picozza, N. P. Topchiev, Paolo Maestro, Andrea Vacchi, L. Bergstrom, P. W. Cattaneo, G. L. Dedenko, Yu. V. Gusakov, S G Bobkov, N. Zampa, O. Adriani, Bohdan Hnatyk, V. G. Zverev, E. M. Tyurin, E. Mocchiutti, P. S. Marrocchesi, M. Ulanov, P. Cumani, A. Rappoldi, V. Bonvicini, V. A. Dogiel, I. V. Arkhangelskaja, S. I. Suchkov, Mark Pearce, S. B. Ricciarini, P. Papini, E. Vannuccini, V. N. Zirakashvili, A.I. Arkhangelskiy, Topchiev, N. P., Galper, A. M., Bonvicini, V., Adriani, O., Aptekar, R. L., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bergstrom, L., Berti, E., Bigongiari, G., Bobkov, S. G., Bogomolov, E. A., Boezio, M., Bongi, M., Bonechi, S., Bottai, S., Boyarchuk, K. A., Vacchi, A., Vannuccini, E., Vasilyev, G. I., Castellini, G., Cattaneo, P. W., Cumani, P., Dedenko, G. L., Dogiel, V. A., De Donato, C., Hnatyk, B. I., Gorbunov, M. S., Gusakov, Y. V., Zampa, N., Zverev, V. G., Zirakashvili, V. N., Kadilin, V. V., Kaplin, V. A., Kaplun, A. A., Korepanov, V. E., Larsson, J., Leonov, A. A., Loginov, V. A., Longo, F., Maestro, P., Marrocchesi, P. S., Mikhailov, V. V., Mocchiutti, E., Moiseev, A. A., Mori, N., Moskalenko, I. V., Naumov, P. Y., Papini, P., Picozza, P., Pearce, M., Popov, A. V., Ryde, F., Rappoldi, A., Ricciarini, S., Runtso, M. F., Serdin, O. V., Sparvoli, R., Spillantini, P., Suchkov, S. I., Tavani, M., Taraskin, A. A., Tiberio, A., Tyurin, E. M., Ulanov, M. V., Fuglesang, C., Kheymits, M. D., and Yurkin, Y. T.

Subjects
Physics, gamma-ray astrophysics, gamma-ray telescopes, Settore FIS/04, Astrophysics::High Energy Astrophysical Phenomena, Dark matter, gamma-ray astrophysic, General Physics and Astronomy, Astronomy, Cosmic ray, Astrophysics, Galaxy, law.invention, Telescope, Physics and Astronomy (all), law, Observatory, Angular resolution, Cosmic rays, Positrons, Telescopes, Gamma rays, Gamma-ray burst, Fermi Gamma-ray Space Telescope
Abstract

The development of the GAMMA-400 ?-ray telescope continues. The GAMMA-400 is designed to measure fluxes of ?-rays and the electron-positron cosmic-ray component possibly associated with annihilation or decay of dark matter particles; and to search for and study in detail discrete ?-ray sources, to measure the energy spectra of Galactic and extragalactic diffuse ?-rays, and to study ?-ray bursts and ?-rays from the active Sun. The energy range for measuring ?-rays and electrons (positrons) is from 100 MeV to 3000 GeV. For 100-GeV ?-rays, the ?-ray telescope has an angular resolution of ~0.01°, an energy resolution of ~1%, and a proton rejection factor of ~5 × 105. The GAMMA-400 will be installed onboard the Russian Space Observatory.

Published
2015
Full Text
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48. Space γ-observatory GAMMA-400 Current Status and Perspectives

Author

V. Bonvicini, Valery Korepanov, V. A. Dogiel, Maxim S. Gorbunov, A. A. Taraskin, E. Mocchiutti, V. A. Loginov, M. Bongi, P. Spillantini, S G Bobkov, P. Yu. Naumov, A. M. Galper, A. Vacchi, Yu. V. Gusakov, Vladimir Kaplin, Mark Pearce, S. B. Ricciarini, E. M. Tyurin, A. Tiberio, P. Papini, L. Bergstrom, Igor V. Moskalenko, E. Vannuccini, M. F. Runtso, Francesco Longo, S. Bottai, V. V. Kadilin, R. L. Aptekar, M. D. Kheymits, I. V. Arkhangelskaja, V. N. Zirakashvili, O. Adriani, V. V. Mikhailov, A. A. Moiseev, Yu. T. Yurkin, O. V. Serdin, S. I. Suchkov, Josefin Larsson, Marco Tavani, P. Picozza, G. L. Dedenko, R. Sparvoli, N. Zampa, Bohdan Hnatyk, V. G. Zverev, G. I. Vasilyev, A.I. Arkhangelskiy, M. Ulanov, Gabriele Bigongiari, Eugenio Berti, P. Cumani, A. Rappoldi, Nicola Mori, C. De Donato, P. S. Marrocchesi, S. Bonechi, A. A. Kaplun, Felix Ryde, G. Castellini, Alexey Leonov, P. W. Cattaneo, E. A. Bogomolov, N. P. Topchiev, Paolo Maestro, Mirko Boezio, Irene V. Arkhangelskaja, Pavel Zh. Buzhan, Galper, A. M., Bonvicini, V., Topchiev, N. P., Adriani, O., Aptekar, R. L., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bergstrom, L., Berti, E., Bigongiari, G., Bobkov, S. G., Boezio, M., Bogomolov, E. A., Bonechi, S., Bongi, M., Bottai, S., Castellini, G., Cattaneo, P. W., Cumani, P., Dedenko, G. L., De Donato, C., Dogiel, V. A., Gorbunov, M. S., Gusakov, Yu. V., Hnatyk, B. I., Kadilin, V. V., Kaplin, V. A., Kaplun, A. A., Kheymits, M. D., Korepanov, V. E., Larsson, J., Leonov, A. A., Loginov, V. A., Longo, F., Maestro, P., Marrocchesi, P. S., Mikhailov, V. V., Mocchiutti, E., Moiseev, A. A., Mori, N., Moskalenko, I. V., Naumov, P. Yu., Papini, P., Pearce, M., Picozza, P., Rappoldi, A., Ricciarini, S., Runtso, M. F., Ryde, F., Serdin, O. V., Sparvoli, R., Spillantini, P., Suchkov, S. I., Tavani, M., Taraskin, A. A., Tiberio, A., Tyurin, E. M., Ulanov, M. V., Vacchi, A., Vannuccini, E., Vasilyev, G. I., Yurkin, Yu. T., Zampa, N., Zirakashvili, V. N., and Zverev, V. G.

Subjects
Physics::Instrumentation and Detectors, Astrophysics::High Energy Astrophysical Phenomena, Dark matter, Cosmic ray, Astrophysics::Cosmology and Extragalactic Astrophysics, Astrophysics, Physics and Astronomy(all), cosmic rays, dark matter, gamma-astronomy, Space (mathematics), Physics and Astronomy (all), Measure (mathematics), law.invention, Telescope, Observatory, law, cosmic ray, Settore FIS/01, Physics, Annihilation, Astrophysics::Instrumentation and Methods for Astrophysics, General Medicine, High Energy Physics::Experiment, Current (fluid)
Abstract

GAMMA-400 γ-ray telescope is designed to measure fluxes of γ-rays and the electron–positron cosmic ray component possibly generated in annihilation or decay of dark matter particles; to search for and study in detail discrete γ-ray sources, to examine the energy spectra of Galactic and extragalactic diffuse γ-rays, to study γ-ray bursts and γ-rays from the active Sun. GAMMA-400 consists of plastic scintillation anticoincidence top and lateral detectors, converter-tracker, plastic scintillation detectors for the time-of-flight system (TOF), two-part calorimeter (CC1 and CC2), plastic scintillation lateral detectors of calorimeter, plastic scintillation detectors of calorimeter, and neutron detector. The converter-tracker consists of 13 layers of double (x, y) silicon strip coordinate detectors (pitch of 0.08mm). The first three and final one layers are without tungsten while the middle nine layers are interleaved with nine tungsten conversion foils. The thickness of CC1 and CC2 is 2 X0 (0.1λ0) and 23 X0 (1.1λ0) respectively (where X0 is radiation length and λ0 is nuclear interaction one). The total calorimeter thickness is 25 X0 or 1.2λ0 for vertical incident particles registration and 54 X0 or 2.5λ0 for laterally incident ones.The energy range for γ-rays and electrons (positrons) registration in the main aperture is from ∼0.1GeV to ∼3.0 TeV. The γ-ray telescope main aperture angular and energy resolutions are respectively ∼0.01 and ∼1% for 102 GeV γ-quanta, the proton rejection factor is ∼5×105. The first three strip layers without tungsten provide the registration of γ-rays down to ∼20 MeV in the main aperture. Also this aperture allows investigating high energy light nuclei fluxes characteristics.Electrons, positrons, light nuclei and gamma-quanta will also register from the lateral directions due to special aperture configuration. Lateral aperture energy resolution is the same as for main aperture for electrons, positrons, light nuclei and gamma-quanta in energy range E>1.0GeV. But using lateral aperture it is possible to detect low-energy gammas in the ranges 0.2 − 10 MeV and 10 MeV – 1.0GeV with energy resolution 8% − 2% and 2% correspondingly accordingly to GAMMA-400 “Technical Project” stage results. Angular resolution in the lateral aperture provides only for low-energy gamma-quanta from non-stationary events (GRB, solar flares and so on) due segments of CC2 count rate analysis.GAMMA-400 γ-ray telescope will be installed onboard the Russian Space Observatory GAMMA-400. The lifetime of the space observatory will be at least seven years. The launch of the space observatory is scheduled for the early 2020s.

Published
2015

49. GAMMA-400 gamma-ray observatory

Author

G. L. Dedenko, Bohdan Hnatyk, V. G. Zverev, J. M. Paredes, I. V. Arkhangelskaja, S. I. Suchkov, M. Bongi, S. Bottai, O.D. Dalkarov, F. Longo, A. A. Moiseev, Yu. T. Yurkin, L. Bergstrom, R. Sparvoli, C. DeDonato, S. G. Bobkov, A. A. Kaplun, David Gascon, E. Mocchiutti, M. F. Runtso, P. Picozza, N. Zampa, P. Spillantini, Nikolay Topchiev, Igor V. Moskalenko, O. Adriani, Mark Pearce, S. B. Ricciarini, J. E. Ward, N. Finetti, P. Papini, E. Vannuccini, M. Tavani, V. V. Mikhailov, E. A. Bogomolov, P. Cumani, Lorenzo Bonechi, A.I. Arkhangelskiy, A. Tiberio, V. N. Zirakashvili, A. L. Menshenin, Yu. I. Stozhkov, A. Rappoldi, V. Bonvicini, Felix Ryde, V. A. Dogiel, G. Castellini, A. V. Bakaldin, P. W. Cattaneo, Valery Korepanov, M. D. Kheymits, M. Ulanov, Yu. V. Gusakov, A. Vacchi, E. M. Tyurin, Maxim S. Gorbunov, Mirko Boezio, A. A. Taraskin, V. A. Loginov, Paolo Maestro, P. S. Marrocchesi, V. V. Kadilin, A. M. Galper, A. Leonov, Nicola Mori, G. I. Vasilyev, O. V. Serdin, Gabriele Bigongiari, Miriam Lucio Martinez, Eugenio Berti, R. Aptekar, Josefin Larsson, P. Yu. Naumov, Vladimir Kaplin, A.M. van den Berg, Topchiev, N. P., Galper, A. M., Bonvicini, V., Adriani, O., Aptekar, R. L., Arkhangelskaja, I. V., Arkhangelskiy, A. I., Bakaldin, A. V., Bergstrom, L., Berti, E., Bigongiari, G., Bobkov, S. G., Boezio, M., Bogomolov, E. A., Bonechi, L., Bongi, M., Bottai, S., Castellini, G., Cattaneo, P. W., Cumani, P., Dalkarov, O. D., Dedenko, G. L., Dedonato, C., Dogiel, V. A., Finetti, N., Gascon, D., Gorbunov, M. S., Gusakov, Yu. V., Hnatyk, B. I., Kadilin, V. V., Kaplin, V. A., Kaplun, A. A., Kheymits, M. D., Korepanov, V. E., Larsson, J., Leonov, A. A., Loginov, V. A., Longo, F., Maestro, P., Marrocchesi, P. S., Martinez, M., Men'Shenin, A. L., Mikhailov, V. V., Mocchiutti, E., Moiseev, A. A., Mori, N., Moskalenko, I. V., Naumov, P. Yu., Papini, P., Paredes, J. M., Pearce, M., Picozza, P., Rappoldi, A., Ricciarini, S., Runtso, M. F., Ryde, F., Serdin, O. V., Sparvoli, R., Spillantini, P., Stozhkov, Yu. I., Suchkov, S. I., Taraskin, A. A., Tavani, M., Tiberio, A., Tyurin, E. M., Ulanov, M. V., Vacchi, A., Vannuccini, E., Vasilyev, G. I., Ward, J. E., Yurkin, Yu. T., Zampa, N., Zirakashvili, V. N., and Zverev, V. G.

Subjects
Physics, Multidisciplinary, Astrophysics::High Energy Astrophysical Phenomena, Dark matter, Gamma ray, FOS: Physical sciences, gamma-ray telescopes, Astrophysics::Cosmology and Extragalactic Astrophysics, Electron, Astrophysics, dark matter, cosmic rays, gamma-ray telescope, Galaxy, law.invention, Telescope, Observatory, law, Physics::Accelerator Physics, Angular resolution, Gamma-ray burst, Astrophysics - Instrumentation and Methods for Astrophysics, Instrumentation and Methods for Astrophysics (astro-ph.IM), Astrophysics::Galaxy Astrophysics
Abstract

The GAMMA-400 gamma-ray telescope with excellent angular and energy resolutions is designed to search for signatures of dark matter in the fluxes of gamma-ray emission and electrons + positrons. Precision investigations of gamma-ray emission from Galactic Center, Crab, Vela, Cygnus, Geminga, and other regions will be performed, as well as diffuse gamma-ray emission, along with measurements of high-energy electron + positron and nuclei fluxes. Furthermore, it will study gamma-ray bursts and gamma-ray emission from the Sun during periods of solar activity. The energy range of GAMMA-400 is expected to be from ~20 MeV up to TeV energies for gamma rays, up to 20 TeV for electrons + positrons, and up to 10E15 eV for cosmic-ray nuclei. For high-energy gamma rays with energy from 10 to 100 GeV, the GAMMA-400 angular resolution improves from 0.1{\deg} to ~0.01{\deg} and energy resolution from 3% to ~1%; the proton rejection factor is ~5x10E5. GAMMA-400 will be installed onboard the Russian space observatory., Comment: 8 pages, 2 figures, 2 tables, submitted to the proceedings of ICRC2015

Published
2015

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