Wide-Field Gamma-Spectrometer BDRG: GRB Monitor On-Board the Lomonosov Mission

Свертилов, С. И.; Panasyuk, M. I.; Bogomolov, V. V.; Amelushkin, A. M.; Barinova, V. O.; Галкин, В. И.; Iyudin, A. F.; Кузнецова, Е. А.; Prokhorov, A. V.; Petrov, V.; Rozhkov, G. V.; Yashin, I. V.; Gorbovskoy, E.; Lipunov, V.; Park, I. H.; Jeong, S.; Kim, M. B.

doi:10.1007/s11214-017-0442-9

Cited by 15 publications

(14 citation statements)

References 33 publications

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“…The GFM instrument should provide the monitor type observations of the upper atmosphere in the hard X-rays and soft gamma-rays, in an energy range of 0.01-3.0 MeV, with the possibility of rough localization of the TGF source. GFM will consist of three identical detector units, which are similar to the detector unit used as gammaray burst monitor of the Lomonosov mission (Svertilov et al 2018). This detector is also the successor of detectors that successfully registered TGF on the Vernov satellite (Bogomolov et al (2017)).…”

Section: Gamma-ray Flash Monitormentioning

confidence: 99%

Universat-SOCRAT multi-satellite project to study TLEs and TGFs

Panasyuk

Климов

Свертилов

et al. 2019

Prog Earth Planet Sci

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We present concept of a new multi-satellite Universat-SOCRAT project aimed to study transient phenomena in the upper atmosphere such as transient luminous events (TLEs) and terrestrial gamma-ray flashes (TGFs). It is a new space project of Lomonosov Moscow State University based on the use of a few satellites in the near-Earth orbit for real-time monitoring of radiation environment, natural (asteroids, meteoroids) and artificial (space debris) potentially dangerous objects, electromagnetic transients including cosmic gamma-ray bursts, terrestrial gamma-ray flashes, and optical and ultraviolet bursts in the Earth's atmosphere. Study of TLEs and TGFs remains an important and demanding task despite of a multitude of recently acquired data for these phenomena. This might be explained by the absence of comprehensive theoretical understanding of physical nature of high-energy processes in the Earth's atmosphere. Multi-wavelength synchronous observations with moderate accuracy of localization of TGF and TLE events are necessary to gain an insight of physics governing these high-energy processes in the Earth's atmosphere. In the article, we present results of TLE observations in space experiments of Moscow State University and discuss advanced instruments for optical observations of TLEs, as well as gamma-ray burst monitor and tracking gamma spectrometer for TGFs observations.

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Section: Gamma-ray Flash Monitormentioning

confidence: 99%

Universat-SOCRAT multi-satellite project to study TLEs and TGFs

Panasyuk

Климов

Свертилов

et al. 2019

Prog Earth Planet Sci

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“…The BDRG [5] and UBAT (UFFO Burst Alert Telescope) [6] devices are based on di erent princi-ff ples for the detection of hard X-ray emission onboard the Lomonosov spacecraft. Each is able to record GRBs and transmit the corresponding signals to the MASTER-SHOK devices in real time.…”

Section: Equipmentmentioning

confidence: 99%

“…Each is able to record GRBs and transmit the corresponding signals to the MASTER-SHOK devices in real time. The BDRG [5]consists of three identical NaI(Tl)/CsI(Tl) scintillator detector units directed toward di erent sectors of ff the sky, which are able to determine the position of a new source on the sky from the di erences between ff the count rates of each of the detectors. The UBAT [6] is part of the Ultra-Fast Flash Observatory (UFFO) onboard the Lomonosov; this is an X-ray telescope with a coded mask.…”

Section: Equipmentmentioning

confidence: 99%

“…4) includes eight observatories: MASTER-Amur, MASTER-Tunka, MASTER-Ural, MAS-TER-Kislovodsk, MASTER-Tavrida (Russian Fed-eration), MASTER-SAAO (South Africa), MAS-TER-IAC (Spain, Canarias), and MASTER-OAFA (Argentina) [4]. Each of these observatories is able to survey 128 deg 2 /hour with a limiting magnitude of 20 m on dark, moonless nights, and each is equipped with two wideangle optical telescopes with a total field of view of 8 deg 2 , a 4098 × 4098 pixel CCD camera with a scale of 1.85 /pixel, and a photometer with Johnson BVRI filters and polarizers [5,16]. All alerts from onboard the Lomonosov Space Observatory are transmitted to the Earth through the Globalstar channels with a minimum time delay, making it possible for any telescope in the world to observe a GRB registered by the Lomonosov mis-sion.…”

Section: Collaboration Between Shok and The Master Global Roboticmentioning

confidence: 99%

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Observations of Near-Earth Optical Transients with the Lomonosov Space Observatory

et al. 2018

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The results of observations with the MASTER-SHOK robotic wide-field optical cameras onboard the Lomonosov Space Observatory carried out in 2016 are presented. In all, the automated transient detection system transmitted 22 181 images of moving objects with signal-to-noise ratios greater than 5 to the Earth. Approximately 84% of these images are identified with well-known artificial Earth satellites (including repeated images of the same satellite) and fragments of such satellites (space debris), according to databases of known satellites. The remaining 16% of the images are relate to uncatalogued objects. This first experience in optical space-based monitoring of near-Earth space demonstrates the high e ciency and great ffi potential of using large-aperture cameras in space, based on the software and technology of the MASTER robotic optical complexes (the Mobile Astronomical System of TElescope-Robots (MASTER) global network of robotic telescopes of Lomonosov Moscow State University).

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“…The Fermi gamma-ray telescope [10], launched in 2008 with an unrivaled spectral range, provides new data on gamma-ray emissions from GRBs. Other space missions for the observation of GRBs are INTEGRAL [11], AGILE [12], Suzaku [13], MAXI/ISS [14], the Interplanetary Network (IPN) [15,16] satellites, and the recent but short-lived BDRG/Lomonosov [17] and UFFO/Lomonosov [18].…”

Section: Introductionmentioning

confidence: 99%

Detection of Low-Energy X-rays Using YSO Scintillation Crystal Arrays for GRB Experiments

et al. 2021

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We developed an X-ray detector using 36 arrays, each consisting of a 64-pixellated yttrium oxyorthosilicate (YSO) scintillation crystal and a 64-channel multi-anode photomultiplier tube. The X-ray detector was designed to detect X-rays with energies lower than 10 keV, primarily with the aim of localizing gamma-ray bursts (GRBs). YSO crystals have no intrinsic background, which is advantageous for increasing low-energy sensitivity. The fabricated detector was integrated into UBAT, the payload of the Ultra-Fast Flash Observatory (UFFO)/Lomonosov for GRB observation. The UFFO was successfully operated in space in a low-Earth orbit. In this paper, we present the responses of the X-ray detector of the UBAT engineering model identical to the flight model, using 241Am and 55Fe radioactive sources and an Amptek X-ray tube. We found that the X-ray detector can measure energies lower than 5 keV. As such, we expect YSO crystals to be good candidates for the X-ray detector materials for future GRB missions.

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Wide-Field Gamma-Spectrometer BDRG: GRB Monitor On-Board the Lomonosov Mission

Cited by 15 publications

References 33 publications

Universat-SOCRAT multi-satellite project to study TLEs and TGFs

Universat-SOCRAT multi-satellite project to study TLEs and TGFs

Observations of Near-Earth Optical Transients with the Lomonosov Space Observatory

Detection of Low-Energy X-rays Using YSO Scintillation Crystal Arrays for GRB Experiments

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