排序方式: 共有15条查询结果,搜索用时 15 毫秒
11.
L. M. Zelenyi A. V. Gurevich S. I. Klimov V. N. Angarov O. V. Batanov A. V. Bogomolov V. V. Bogomolov L. Bodnar D. I. Vavilov G. A. Vladimirova G. K. Garipov V. M. Gotlib M. B. Dobriyan M. S. Dolgonosov N. A. Ivlev A. V. Kalyuzhnyi V. N. Karedin S. O. Karpenko V. M. Kozlov I. V. Kozlov V. E. Korepanov A. A. Lizunov A. A. Ledkov V. N. Nazarov M. I. Panasyuk A. P. Papkov V. G. Rodin P. Segedi S. I. Svertilov A. A. Sukhanov Ch. Ferenz N. A. Eysmont I. V. Yashin 《Cosmic Research》2014,52(2):87-98
12.
A. M. Amelyushkin V. I. Galkin B. V. Goncharov E. S. Gorbovskoy V. G. Kornilov V. M. Lipunov M. I. Panasyuk V. L. Petrov G. F. Smoot S. I. Svertilov N. N. Vedenkin I. V. Yashin 《Cosmic Research》2013,51(6):434-438
One of the goals of the Lomonosov satellite designed by scientists of Moscow State University is to study the prompt emission of cosmic gamma-ray bursts. This paper describes the gamma-ray burst monitor in the gamma-ray range (the BDRG instrument) and the wide-field optical cameras (the SHOK instrument) for detecting both the gamma-ray burst prompt emission and its precursors. 相似文献
13.
M.I. Kudryavtsev A.V. Bogomolov V.V. Bogomolov Yu.I. Denisov S.I. Svertilov 《Advances in Space Research (includes Cospar's Information Bulletin, Space Research Today)》1998,21(12):1785-1788
The measurements of high-energy neutron (with energies 30–300 MeV) and proton (with energies 1–200 MeV) fluxes are being conducted on-board “Mir-Spectr” orbital complex. Neutrons are detected by the undirected (FOV 4π sr) scintillator spectrometer, consisting of 4 identical CsI(Tl) detector units (the effective area for neutrons 30 cm2). The gamma-quanta, which can be also detected by this instrument, are separated from neutrons by the analysis of the scintillator output pulse shape. To exclude registration of charged particles an anticoincidence plastic scintillator shield is realized in each detector unit. The proton fluxes are measured by the telescope based on 3 semiconductor detectors with small geometry factor (1 cm2×sr). As the first result of the experiment the upper limit of the integral flux of local and albedo neutrons in the equatorial region (L<1.1) was estimated. The results of this measurements can be useful for the radiation security. Also, the neutrons of solar flares can be detected in this experiment. 相似文献
14.
We present the characteristics of short (duration less than 1 min) increases of the counting rate of electrons with energies >0.08 MeV observed in low-latitude (L < 2.0) regions of near-Earth space in the course of the GRIF experiment on the Spektr module of the Mir orbital station. The measurements were carried out using a set of instruments including X-ray and gamma-ray spectrometers, as well as detectors of electrons, protons, and nuclei with large and small geometrical factors, which allowed one to detect the fluxes of charged particles both in the region of the Earth’s radiation belts and in regions close to the geomagnetic equator. As a result of more than 1.5 years of observation, it is demonstrated that short increases in the intensity of electrons of subrelativistic energies are detected not only in the regions of the near-Earth space known as “precipitation zones” (1.7 < L < 2.5), but in high-latitude regions (up to the geomagnetic equator, L < 1.1) as well. Two types of increases of the electron counting rate are found: either fairly regular increases repeating on successive orbits or increases local in time. The latter type of increases can be caused by a short enhancement of electron flux on a given drift shell. The results of our measurements have shown that the duration of the detected increases in intensity can be rather short, as little as 20–30 s. Therefore, in the case of large amplitudes, such increases of the counting rate of electrons can imitate astrophysical events of the type of cosmic gamma-ray bursts in the detectors of hard X-ray and gamma radiation. 相似文献
15.
V. A. Sadovnichiy A. M. Amelyushkin V. Angelopoulos V. V. Bengin V. V. Bogomolov G. K. Garipov E. S. Gorbovskoy B. Grossan P. A. Klimov B. A. Khrenov Jeark Lee V. M. Lipunov Gi Wu Na M. I. Panasyuk I. H. Park V. L. Petrov C. T. Russell S. I. Svertilov E. A. Sigaeva G. F. Smoot Yu. Shprits N. N. Veden’kin I. V. Yashin 《Cosmic Research》2014,52(3):250-250