Рейтинг (ПРНД) сотрудников ИЯИ РАН сезона 2021 [306]

по группам: Теоретическая физика, Ядерная физика, Нейтринная физика и КЛ, физика Частиц, Ускорительная физика, Междисциплинарные исследования
ФИОГРПРНДк-т умно
жения		дата
Воронин Дмитрий МихайловичН207,61,5а20.01.2021
Воронин Дмитрий Михайлович
Аспирант 3-го года обучения, стажер-исследователь, ОЭФ

Воронин Дмитрий Михайлович, стажер-исследователь, ОЭФ
1.   V. B. Petkov, A. N. Fazliakhmetov, A. M. Gangapshev, …, D. M. Voronin et al. Baksan large volume scintillation telescope: a current status // Journal of Physics: Conference Series, 1468,012244 (2020). DOI:10.1088/1742-6596/1468/1/012244
30*0.574*0.125*1.5=3.22875
2.   N. Budnev, I. Astapov, P. Bezyazeekov, …, D. Voronin et al. TAIGA—an advanced hybrid detector complex for astroparticle physics and high energy gamma-ray astronomy in the Tunka valley // (2020) Journal of Instrumentation, V.15, C09031. DOI:10.1088/1748-0221/15/09/c09031
30*1.454*0.07*1.5=4.5801
3.   D. Chernov, I. Astapov, P. Bezyazeekov, …, D. Voronin et al. Development of a novel wide-angle gamma-ray imaging air Cherenkov telescope with SiPM-based camera for the TAIGA hybrid installation // (2020) Journal of Instrumentation, V.15, C09062. DOI:10.1088/1748-0221/15/09/C09062
30*1.454*0.07*1.5=4.5801
4.   A. Ivanova, N. Budnev, A. Chiavassa, …, D. Voronin et al. Design features and data acquisition system of the TAIGA-Muon scintillation array // (2020) Journal of Instrumentation, V.15, C06057. DOI:10.1088/17480221/15/06/C06057
30*1.454*0.07*1.5=4.5801
5.   D. Chernukh, A. Krykov, A. Silaev, …, D. Voronin et al. An approach for identification of ultrahigh energy extensive air showers with scintillation detectors at TAIGA experiment // (2020) Journal of Instrumentation, V.15, C09037. DOI: 10.1088/1748-0221/15/09/C09037
30*1.454*0.07*1.5=4.5801
6.   L. Kuzmichev, I. Astapov, P. Bezyazeekov, ..., D. Voronin et al. Cherenkov EAS arrays in the Tunka astrophysical center: From Tunka-133 to the TAIGA gamma and cosmic ray hybrid detector // (2020) Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 952,161830. DOI: 10.1016/j.nima.2019.01.056
30*1.265*0.07*1.5=3.98475
7.   I. Astapov, P. Bezyazeekov, V. Boreyko, ..., D. Voronin et al. Optimization of electromagnetic and hadronic extensive air shower identification using the muon detectors of the TAIGA experiment // (2020) Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 952,161730. DOI: 10.1016/j.nima.2018.12.045
30*1.265*0.07*1.5=3.98475
8.   Y.M. Malyshkin, A.N. Fazliakhmetov, A.M. Gangapshev, ..., D.M. Voronin et al. Modeling of a MeV-scale particle detector based on organic liquid scintillator // (2020) Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 951,162920. DOI: 10.1016/j.nima.2019.162920
30*1.265*0.125*1.5=7.115625
9.   N.M. Budnev, I.I. Astapov, P.A. Bezyazeekov, …, D.M. Voronin et. al. TAIGA – A Hybrid array for high-energy gamma astronomy and cosmic-ray physics // Nuclear Instruments and Methods in Physics Research, Section A, 2020. V.958. 162113.
30*1.265*0.07*1.5=3.98475
10.   A. Abeln, K. Altenmuller, S. Arguedas Cuendis, …….., D. Voronin et al. Conceptual design of BabyIAXO, the intermediate stage towards the International Axion Observatory // arXiv:2010.12076
3*0.047=0.141
11.   A. Abeln, K. Altenmuller, S. Arguedas Cuendis, …….., D. Voronin et al. Axion search with BabyIAXO in view of IAXO // arXiv:2012.06634
3*0.047=0.141
12.   S. Lubsandorzhiev, A. Sidorenkov, B. Lubsandorzhiev, …, D. Voronin et al. Development of new liquid scintillators for neutrino experiments of next generation // PoS (ICRC2019) 946
8х0,125х1,5=1.5
13.   S. Lubsandorzhiev, B. Lubsandorzhiev, E. Vyatchin, …, D. Voronin et al. Imitators of Cherenkov and scintillation light pulses based on fast LEDs // PoS (ICRC2019) 947
8х0,3х1,5=3,6
14.   S. Lubsandorzhiev, A. Sidorenkov, B. Lubsandorzhiev, …, D. Voronin et al. Development of medium and small size photomultipliers for experiments in neutrino physics // PoS (ICRC2019) 948
8х0,125х1,5=1.5
15.   A.E. Kaloshin, D.M. Voronin. Neutrino propagation in media and axis of complete polarization // European Physical Journal C. (2019)79:153.
30*4.389*0.65=85.5586
16.   R.D. Monkhoev, I.I. Astapov, P.A. Bezyazeekov, …, D.M. Voronin et. al. Search for Diffuse Gamma Rays Using Data of the Tunka-GRANDE Experiment // Bull. Russ. Acad. Sci. 83 (2019) 8. 959-961. DOI: 10.3103/S1062873819080306
8*0.07*1.5=0.84
17.   N. Lubsandorzhiev, I. Astapov, P. Bezyazeekov, …, D.M. Voronin et al. The hybrid installation TAIGA: design, status and preliminary results // PoS (ICRC2019) 729.
8*0.07*1.5=0.84
18.   L. Kuzmichev, I. Astapov, P. Bezyazeekov, …, D.M. Voronin et al. TAIGA:results and perspective // The European Physical Journal Conferences 207(5):03003 (2019)
30*0.296*0.07*1.5=0.9324
19.   V. Prosin, I. Astapov, P. Bezyazeekov, …, D.M. Voronin et al. Cosmic Ray Energy Spectrum derived from the Data of EAS Cherenkov Light Arrays in the Tunka Valley // The European Physical Journal Conferences 210:01003 (2019).
30*0.296*0.07*1.5=0.9324
20.   D. Kostunin, I.I. Astapov, P.A. Bezyazeekov, …, D. Voronin et. Tunka Advanced Instrument for cosmic ray and Gamma Astronomy // J. Phys.: Conf. Ser. 2019. V.1263. 012006
0,574х30х0,07х1,5=1,8081
Итого: 138,413
Повышающий коэффициент 1,5
ПРНД = 138,413*1.5=207,62