Рейтинг (ПРНД) сотрудников ИЯИ РАН сезона 2022 [312]

по группам: Теоретическая физика, Ядерная физика, Нейтринная физика и КЛ, физика Частиц, Ускорительная физика, Междисциплинарные исследования
по должностям и регионам: Москва, научные Сотрудники (по Указу), научные Работники (вне Указа), Аспиранты, стуДенты, внешние совМестители, Сб...Мб - то же для БНО
ФИОГРПРНДдатадолжн
Дорошкевич Евгений АндреевичЧ119,518.01.2022С
Дорошкевич Евгений Андреевич
Кандидат физико-математических наук, старший научный сотрудник лаборатории гамма - астрономии и реакторных нейтрино ОЭФ

2020

1. M. Agostini, A.M. Bakalyarov, M. Balata, ………, E. Doroshkevich et al. Modeling of GERDA phase II data // JHEP 03(2020)139
5,81х30х0,047=8,1921
2. M. Agostini, A.M. Bakalyarov, M. Balata, ………, E. Doroshkevich, et al. Searching for neutrinoless double beta decay with GERDA // J. Phys.: Conf. Ser. 2020. V.1342. P.012005
0,547х30х0,047=0,7713
3. M. Agostini, A.M. Bakalyarov, M. Balata, ………, E. Doroshkevich, et al. The first search for bosonic super-WIMPs with masses up to 1 MeV/c2 with GERDA // Physical Review Letters. 2020. 125. 011801.
9,161х30х0,047=12,917
4. M. Agostini, A.M. Bakalyarov, M. Balata, ………, E. Doroshkevich, et al. Final result of GERDA on the search for neutrinoless double-? decay // Physical Review Letters. 2020. Vol.125. Issue 25. 252502.
9,161х30х0,047=12,917
5. M. Agostini, A.M. Bakalyarov, M. Balata, ………, E. Doroshkevich, et al. Searching for neutrinoless double beta decay with GERDA // J. Phys.: Conf. Ser. 2020. V.1342. P.012005
0,547х30х0,047=0,7713
6. P. Adlarson, W. Augustyniak, W. Bardan, ……, E. Doroshkivich et al. Differential Cross Sections for Neutron-Proton Scattering in the Region of the d?(2380) Dibaryon Resonance. Phys. Rev. C. 102 (2020) no.1, 015204
3,296х30х0,047=4,64736
7. Angel Abusleme, Thomas Adam, Shakeel Ahmad, ……., E. Doroshkevich, et al. TAO Conceptual Design Report // arXiv:2005.08745.
3х0,018=0,054
8. M. Agostini, A.M. Bakalyarov, M. Balata, ………, E. Doroshkevich, et al. The first search for bosonic super-WIMPs with masses up to 1 MeV/c2 with GERDA // arXiv:2005.14184.
3х0,047=0,141
9. Angel Abusleme, Thomas Adam, Shakeel Ahmad, ……., E. Doroshkevich, et al. Feasibility and physics potential of detecting 8B solar neutrinos at JUNO // arXiv:2006.11760
3х0,018=0,054
10. A. Abusleme, T. Adam, S. Ahmad, ……., E. Doroshkevich, et al. Optimization of the JUNO liquid scintillator composition using a Daya Bay antineutrino detector // arXiv: 2007.00023
3х0,018=0,054
11. M. Agostini, A.M. Bakalyarov, M. Balata, ………, E. Doroshkevich, et al. Final result of GERDA on the search for neutrinoless double-? decay // arXiv:2009.06079.
3х0,047=0,141
12. A. Abusleme, T. Adam, S. Ahmad, ……., E. Doroshkevich, et al. Calibration strategy of the JUNO experiment // arXiv:2011.06405
3х0,018=0,054

40,7141

Курс лекций

Теория групп в физике элементарных частиц (ИГУ и НИИПФ ИГУ)
30

70,7141

2021
1. A. Abusleme, T. Adam, S. Ahmad, …, E. Doroshkevich, et al. Feasibility and physics potential of detecting 8B solar neutrinos at JUNO // Chinese Physics C, 2021, Vol. 45, No. 2 P.023004
2,145x30x0,018=1,158
2. Chuanya Cao, Jilei Xu, Miao He, ………, E. Doroshkevich, et al. Mass production and characterization of 3-inch PMTs for the JUNO experiment // arXiv: 2102.11538
3х0,018=0,054
3. A. Abusleme, T. Adam, S. Ahmad, ……., E. Doroshkevich, et al. Calibration strategy of the JUNO experiment // JHEP 03(2021)004.
5,81х0,018х30=3,137
4. Agostini, A.M. Bakalyarov, M. Balata, ………, E. Doroshkevich, et al. Calibration of the GERDA experiment // arXiv:2103.13777
3х0,047=0,141
5. A. Abusleme, T. Adam, S. Ahmad, …..…., E. Doroshkevich, et al. Measuring low energy atmospheric neutrino with the JUNO detector // arXiv:2103.09908
3х0,018=0,054
6. N.Chau,….,E.Doroshkevich et al. Neutrino mass ordering determination through combined analysis with JUNO and KM3NeT/ORCA //
JINST 16 (2021) 11, C11007
1,415х30х0,047=1,9952
7. Agostini, A.M. Bakalyarov, M. Balata, ………, E. Doroshkevich, et al. Characterization of inverted coaxial 76Ge detectors in GERDA for future double-? decay experiments // arXiv:2103.15111. (Submitted to EPJC)
3х0,047=0,141
8. A. Abusleme, T. Adam, S. Ahmad, …..…., E. Doroshkevich, et al. The Design and Sensitivity of JUNO's scintillator radiopurity pre-detector OSIRIS // arXiv:2103.16900
3х0,018=0,054
9. A. Abusleme, T. Adam, S. Ahmad, …..…., E. Doroshkevich, et al. JUNO Physics and Detector // arXiv:2104.02565
3х0,018=0,054
10. Chuanya Cao, Jilei Xu, Miao He, ………, E. Doroshkevich, et al. Mass production and characterization of 3-inch PMTs for the JUNO experiment // Nuclear Instruments and Methods A. 2021. V.1005. P.165347.
1,455х0,07х30=3,056
11. A. Abusleme, T. Adam, S. Ahmad, ……., E. Doroshkevich, et al. Optimization of the JUNO liquid scintillator composition using a Daya Bay antineutrino detector // Nuclear Instruments and Methods A. 2021. Vol.988. P.164823
1,455х0,018х30=0,786
12. M. Agostini, A.M. Bakalyarov, M. Balata, ………, E. Doroshkevich, et al. Characterization of inverted coaxial 76Ge detectors in GERDA for future double-? decay experiments // EPJC. 2021 81:505
4,59х0,047х30=6,472
13. Angel Abusleme, Thomas Adam, Shakeel Alhmad, ……….., E. Doroshkevich, et al. Radioactivity control strategy for the JUNO detector // arXiv:210703669
3х0,018=0,054
14. M. Agostini, A.M. Bakalyarov, M. Balata, ………, E. Doroshkevich, et al. Calibration of the GERDA experiment // EPJC (2021) 81: 682.
4,59х0,047х30=6,472
15. S. Aiello, A. Albert, M. Alshamsi, ………. , E. Doroshkevich, et al. Combined sensitivity of JUNO and KM3NeT/ORCA to the neutrino mass ordering // arXiv:2108.06293
3х0,028=0,084
16. A. Abusleme, T. Adam, S. Ahmad, ………., E. Doroshkevich, et al. Juno Physics Prospects // PoS(ICRC2021)1194
8х0,018=0,144
17. A. Abusleme, T. Adam, S. Ahmad, …..…., E. Doroshkevich, et al. JUNO sensitivity to low energy atmospheric neutrino spectra // EPJC, 2021, 81:887.
4,59х0,018х30=2,479
18. A. Abusleme, T. Adam, S. Ahmad, …..…., E. Doroshkevich, et al. The Design and Sensitivity of JUNO's scintillator radiopurity pre-detector OSIRIS // EPJC 2021 81(973)
4,59х0,018х30=2,479
19. Angel Abusleme, Thomas Adam, Shakeel Alhmad, ……….., E. Doroshkevich, et al. Radioactivity control strategy for the JUNO detector // JHEP 11(2021)102
5,81х0,018х30=3,137
20. A. Abusleme, T. Adam, S. Ahmad, …..…., E. Doroshkevich, et al. JUNO Physics and Detector // Progress in Particle and Nuclear Physics. 2021, 103927. doi: https://doi.org/10.1016/j.ppnp.2021.103927
16,281x30x0,018=8,7917
21. Jun Wang, Jiajun Liao, Wei Wang, Angel Abusleme, ………., E. Doroshkevich, et al. Damping signatures at JUNO, a medium-baseline reactor neutrino oscillation experiment // arXiv:2112.14450.
3х0,018=0,054

40,7969

Курс лекций
Чтение курса лекций. Теория групп в физике элементарных частиц (ИГУ и НИИПФ ИГУ) 8

48,7969

119,511