Your search keyword '"Arzhannikov, A. V."' showing total 457 results

1. Two-dimensional distributed feedback as a method for generation of powerful coherent radiation from spatially-extended relativistic electron beams

Author

Ginzburg, Naum Samuilovich, Peskov, Nikolai Yu., Sergeev, Aleksandr Sergeevich, Zaslavskij, Vladislav Jurevich, Arzhannikov, A. V., and Sinitsky, S. L.

Subjects

лазеры и мазеры на свободных электронах, мощное когерентное микроволновое излучение, двумерная распределенная обратная связь, одномодовая и многомодовая генерация, Physics, QC1-999

Abstract

The purpose of the research presented in the review is to analyze a new feedback mechanism Џ two-dimensional (2D) distributed feedback, and to study the possibility of using this mechanism for generation of powerful spatially-coherent radiation. Such 2D distributed feedback is implemented by applying 2D Bragg structures, which represent sections of planar or coaxial waveguides with the 2D-periodical corrugation and can be considered as an analog of the 2D photonic crystals. Methods. Theoretical analysis of 2D Bragg structures and powerful relativistic masers based on them was carried out in the framework of the coupled-waves method using geometrical and quasi-optical approximations. High selectivity of 2D Bragg structures was confirmed by the simulations and «cold» electrodynamic tests. Results. Simulations of the dynamics of oscillators with 2D distributed feedback shows that the transverse (relative to the electron beam propagation) wave-fluxes that occur in 2D Bragg structures lead to synchronization of the radiation of different parts of wide electron beams and establishment of a stable single-mode generation at the transverse sizes of the systems of up to ∼ 102 ...103 wavelengths. Operability of novel feedback mechanism has been demonstrated experimentally in planar and coaxial Free-Electron Masers realized in the 4-mm and 8-mm wavelength bands, where a stable narrow-band generation with a record output power of up to 100 MW level is achieved at the transverse sizes of the system of about 50 wavelengths. Conclusion. Theoretical and experimental studies have shown that the 2D distributed feedback is an effective method for obtaining coherent radiation of millimeter and submillimeter ranges with a power level of ∼ 108 ...1010 W from relativistic electron beams of sheet and tubular configurations formed by the high-current accelerators. From a practical point of view, it also attractive to use the 2D feedback mechanism for synchronization of a laser active media, in particular, semiconductor heterolasers.

Published

2020

2. The Frequency Spectrum and Energy Content in a Pulse Flux of Terahertz Radiation Generated by a Relativistic Electron Beam in a Plasma Column with Different Density Distributions

Author

Arzhannikov, A. V., Sinitsky, S. L., Samtsov, D. A., Timofeev, I. V., Sandalov, E. S., Popov, S. S., Atlukhanov, M. G., Makarov, M. A., Kalinin, P. V., Kuklin, K. N., Rovenskikh, A. F., and Stepanov, V. D.

Published

2024

3. Magnetic System of a Sub-Gigawatt Free-Electron Laser of the Terahertz Range Based on a Kiloampere Beam of Relativistic Electrons

Author

Sandalov, E. S., Sinitsky, S. L., Arzhannikov, A. V., Pavlyuchenko, V. A., Bak, P. A., Ginzburg, N. S., Logachev, P. V., Mescheryakov, I. N., Nikiforov, D. A., Peskov, N. Yu., Protas, R. V., Ryabchenko, K. K., and Skovorodin, D. I.

Published

2023

4. Pulsed Power and Spectrum Composition of the Terahertz Radiation Flux Escaping from a Plasma Column Due to Propagation Through it of a Relativistic Electron Beam with Various Current Densities (GOL–PET Facility Experiments)

Author

Samtsov, D. A., Arzhannikov, A. V., Sinitsky, S. L., Kalinin, P. V., Popov, S. S., Sandalov, E. S., Atlukhanov, M. G., Kuklin, K. N., Makarov, M. A., Stepanov, V. D., and Rovenskikh, A. F.

Published

2023

5. Design and Simulation of High-Power Planar Čerenkov Oscillators with Two-Dimensional Distributed Feedback in the Subterahertz Frequency Range

Author

Peskov, N. Yu., Zaslavsky, V. Yu., Ginzburg, N. S., Malkin, A. M., Savilova, A. A., Sergeev, A. S., Arzhannikov, A. V., Kalinin, P. V., Sandalov, E. S., Sinitsky, S. L., and Stepanov, V. D.

Published

2023

6. High-Power Spatially Extended Free-Electron Masers with Three-Dimensional Distributed Feedback

Author

Peskov, N. Yu., Egorova, E. D., Ginzburg, N. S., Sergeev, A. S., Arzhannikov, A. V., and Sinitsky, S. L.

Published

2023

7. Energy Content and Spectral Composition of a 5-µs-Long Flux of Submillimeter Radiation Generated in Plasma during REB Relaxation

Author

Arzhannikov, A. V., Sinitsky, S. L., Samtsov, D. A., Sandalov, E. S., Popov, S. S., Altukhanov, M. G., Makarov, M. A., Kalinin, P. V., Kuklin, K. N., Rovenskikh, A. F., and Stepanov, V. D.

Published

2022

8. Frequency Spectrum of the Radiation Flow in the Frequency Range 0.1–0.6 THZ Generated at the GOL–PET Facility Under Various Conditions

Author

Samtsov, D. A., Arzhannikov, A. V., Sinitsky, S. L., S.Popov, S., Kalinin, P. V., Sandalov, E. S., G.Atlukhanov, M., Morozov, O. P., Kuklin, K. N., Makarov, M. A., Rovenskikh, A. F, and Stepanov, V. D.

Published

2022

9. Magnetic System of a Sub-Gigawatt Free-Electron Laser of the Terahertz Range Based on a Kiloampere Beam of Relativistic Electrons

Author

Sandalov, E. S., primary, Sinitsky, S. L., additional, Arzhannikov, A. V., additional, Pavlyuchenko, V. A., additional, Bak, P. A., additional, Ginzburg, N. S., additional, Logachev, P. V., additional, Mescheryakov, I. N., additional, Nikiforov, D. A., additional, Peskov, N. Yu., additional, Protas, R. V., additional, Ryabchenko, K. K., additional, and Skovorodin, D. I., additional

Published

2024

10. Pulsed Power and Spectrum Composition of the Terahertz Radiation Flux Escaping from a Plasma Column Due to Propagation Through it of a Relativistic Electron Beam with Various Current Densities (GOL–PET Facility Experiments)

Author

Samtsov, D. A., primary, Arzhannikov, A. V., additional, Sinitsky, S. L., additional, Kalinin, P. V., additional, Popov, S. S., additional, Sandalov, E. S., additional, Atlukhanov, M. G., additional, Kuklin, K. N., additional, Makarov, M. A., additional, Stepanov, V. D., additional, and Rovenskikh, A. F., additional

Published

2024

11. High-Power Spatially Extended Free-Electron Masers with Three-Dimensional Distributed Feedback

Author

Peskov, N. Yu., primary, Egorova, E. D., additional, Ginzburg, N. S., additional, Sergeev, A. S., additional, Arzhannikov, A. V., additional, and Sinitsky, S. L., additional

Published

2024

12. Development of High-Power Long-Pulse Submillimeter-Wave Free-Electron Lasers on the Basis of the Linear Induction Accelerator Complex

Author

Arzhannikov, A. V., Bak, P.A., Belousov, V. I., Ginzburg, N. S., Zaslavsky, V.Yu., Nikiforov, D.A., Peskov, N.Yu., Sandalov, E. S., Sinitsky, S. L., Sobolev, D. I., Starostenko, A. A., and Zhivankov, K. I.

Published

2022

13. Excitation of ship waves by a submerged object: new solution to the classical problem

Author

Arzhannikov, Anrei V. and Kotelnikov, Igor A.

Subjects

Physics - Fluid Dynamics

Abstract

We have proposed a new method for solving the problem of ship waves excited on the surface of a non-viscous liquid by a submerged object that moves at a variable speed. As a first application of this method, we have obtained a new solution to the classic problem of ship waves generated by a submerged ball that moves rectilinearly with constant velocity parallel to the equilibrium surface of the liquid. For this example, we have derived asymptotic expressions describing the vertical displacement of the liquid surface in the limit of small and large values of the Froude number. The exact solution is presented in the form of two terms, each of which is reduced to one-dimensional integrals. One term describes the "Bernoulli hump" and another term the "Kelvin wedge." As a second example, we considered vertical oscillation of the submerged ball. In this case, the solution leads to the calculation of one-dimensional integral and describes surface waves propagating from the epicenter above the ball., Comment: Submitted to Physical Review A

Published

2016

14. Maintaining the close-to-critical state of thorium fuel core of hybrid reactor operated under control by D-T fusion neutron flux

Author

Bedenko, Sergey V., Arzhannikov, Andrey V., Lutsik, Igor O., Prikhodko, Vadim V., Shmakov, Vladimir M., Modestov, Dmitry G., Karengin, Alexander G., and Shamanin, Igor V.

Published

2021

15. Facility to study neutronic properties of a hybrid thorium reactor with a source of thermonuclear neutrons based on a magnetic trap

Author

Arzhannikov, Andrey V., Shmakov, Vladimir M., Modestov, Dmitry G., Bedenko, Sergey V., Prikhodko, Vadim V., Lutsik, Igor O., and Shamanin, Igor V.

Published

2020

16. A High-Power Planar W-Band Čerenkov Maser with Two-Dimensional Distributed Feedback: Design Elements and Modeling Results

Author

Peskov, N.Yu., Vikharev, A. A., Ginzburg, N. S., Zaslavsky, V.Yu., Malkin, A. M., Sergeev, A. S., Arzhannikov, A. V., Kalinin, P. V., Sandalov, E. S., Sinitskiy, S. L., and Stepanov, V.D.

Published

2020

17. Preparation of Graphene Layers Using Microwave Exfoliation of Fluographite Intercalation Compounds

Author

Makotchenko, V. G., Saprykin, A. I., Mikheev, A. N., and Arzhannikov, A. V.

Published

2020

18. Generation of powerful terahertz emission in a beam-driven strong plasma turbulence

Author

Arzhannikov, A. V. and Timofeev, I. V.

Subjects

Physics - Plasma Physics

Abstract

Generation of terahertz electromagnetic radiation due to coalescence of upper-hybrid waves in the long-wavelength region of strong plasma turbulence driven by a high-current relativistic electron beam in a magnetized plasma is investigated. The width of frequency spectrum as well as angular characteristics of this radiation for various values of plasma density and turbulence energy are calculated using the simple theoretical model adequately describing beam-plasma experiments at mirror traps. It is shown that the power density of electromagnetic emission at the second harmonic of plasma frequency in the terahertz range for these laboratory experiments can reach the level of 1 ${MW/cm}^3$ with 1% conversion efficiency of beam energy losses to electromagnetic emission.

Published

2012

19. Beam-Plasma Generator of the THz Radiation Based on an Induction Accelerator (LIA-PET Project)

Author

Arzhannikov, A. V., primary, Sinitsky, S. L., additional, Starostenko, D. F., additional, Logachev, P. V., additional, Bak, P. A., additional, Nikiforov, D. A., additional, Popov, S. S., additional, Kalinin, P. V., additional, Samtsov, D. A., additional, Sandalov, E. S., additional, Atlukhanov, M. G., additional, Grigoriev, A. N., additional, Vorobyov, S. O., additional, Petrov, D. V., additional, and Protas, R. V., additional

Published

2023

20. Plasma Heating by an Electron Beam in Corrugated Magnetic Field

Author

Postupaev, V. V., Arzhannikov, A. V., Astrelin, V. T., Averkov, A. M., Beklemishev, A. D., Burdakov, A. V., Ivanov, I. A., Ivantsivsky, M. V., Koidan, V. S., Mekler, K. I., Polosatkin, S. V., Rovenskikh, A. F., Sinitsky, S. L., Sulyaev, Yu. S., and Zubairov, E. R.

Subjects

Physics - Plasma Physics

Abstract

New experimental results from the multimirror trap GOL-3 are presented. Deuterium plasma of $~10^21 m^-3$ density is heated by a high power relativistic electron beam (peak parameters are ~1 MeV, ~25 kA, ~8 $\mu$s, ~120 kJ). Magnetic system of the facility is a 12-meter-long axisymmetrical solenoid with corrugated magnetic field, which consists of 55 cells with $B_max/B_min$=4.8/3.2 T. Collective plasma heating by the electron beam results in peak electron temperature ~2 keV. To this time the ions are also collectively heated by gradients of electron pressure in the cells of the trap. Ion temperature increases above 1 keV and confines at the high level for ~1 ms. Dense hot plasma in GOL-3 trap emits D-D neutrons for ~1 ms. Details of collective plasma heating by the beam in the corrugated magnetic field will be presented in the paper. New physical mechanism of effective heating of plasma ions, substantially dependent on the corrugation of the magnetic field, is discussed. Experiments with complete multimirror configuration of the GOL-3 facility have shown the significant improvement of energy confinement time comparing with simple solenoidal configuration. Axial currents, which exist in the system, cause sheared helical structure of the magnetic field. The safety factor q is shown to be below unity on the axis., Comment: 12th International Congress on Plasma Physics, 25-29 October 2004, Nice (France)

Published

2004

21. Bragg Deflectors of Wave Fluxes for High-Power Relativistic Masers

Author

Arzhannikov, A. V., Ginzburg, N. S., Zaslavskii, V. Yu., Kalinin, P. V., Peskov, N. Yu., Sergeev, A. S., and Sinitskii, S. L.

Published

2019

22. Planar THz FELs Based on Intense Parallel Sheet Electron Beams and Intracavity Wave Scattering

Author

Arzhannikov, A. V., Ginzburg, N. S., Zaslavsky, V. Yu., Kalinin, P. V., Peskov, N. Yu., Sandalov, E. S., Sergeev, A. S., Sinitsky, S. L., and Stepanov, V. D.

Published

2019

23. Frequency Spectrum of the Radiation Flow in the Frequency Range 0.1–0.6 THZ Generated at the GOL–PET Facility Under Various Conditions

Author

Samtsov, D. A., primary, Arzhannikov, A. V., additional, Sinitsky, S. L., additional, S.Popov, S., additional, Kalinin, P. V., additional, Sandalov, E. S., additional, G.Atlukhanov, M., additional, Morozov, O. P., additional, Kuklin, K. N., additional, Makarov, M. A., additional, Rovenskikh, A. F, additional, and Stepanov, V. D., additional

Published

2023

24. Figure 4 from: Bedenko SV, Lutsik IO, Matyushin AA, Polozkov SD, Shmakov VM, Modestov DG, Prikhodko VV, Arzhannikov AV (2023) Fusion-fission hybrid reactor facility: power profiling. Nuclear Energy and Technology 9(1): 65-70. https://doi.org/10.3897/nucet.9.102781

Author

Bedenko, Sergey V., primary, Lutsik, Igor O., additional, Matyushin, Anton A., additional, Polozkov, Sergey D., additional, Shmakov, Vladimir M., additional, Modestov, Dmitry G., additional, Prikhodko, Vadim V., additional, and Arzhannikov, Andrey V., additional

Published

2023

25. Figure 1 from: Bedenko SV, Lutsik IO, Matyushin AA, Polozkov SD, Shmakov VM, Modestov DG, Prikhodko VV, Arzhannikov AV (2023) Fusion-fission hybrid reactor facility: power profiling. Nuclear Energy and Technology 9(1): 65-70. https://doi.org/10.3897/nucet.9.102781

Author

Bedenko, Sergey V., primary, Lutsik, Igor O., additional, Matyushin, Anton A., additional, Polozkov, Sergey D., additional, Shmakov, Vladimir M., additional, Modestov, Dmitry G., additional, Prikhodko, Vadim V., additional, and Arzhannikov, Andrey V., additional

Published

2023

26. Figure 3 from: Bedenko SV, Lutsik IO, Matyushin AA, Polozkov SD, Shmakov VM, Modestov DG, Prikhodko VV, Arzhannikov AV (2023) Fusion-fission hybrid reactor facility: power profiling. Nuclear Energy and Technology 9(1): 65-70. https://doi.org/10.3897/nucet.9.102781

Author

Bedenko, Sergey V., primary, Lutsik, Igor O., additional, Matyushin, Anton A., additional, Polozkov, Sergey D., additional, Shmakov, Vladimir M., additional, Modestov, Dmitry G., additional, Prikhodko, Vadim V., additional, and Arzhannikov, Andrey V., additional

Published

2023

27. Figure 2 from: Bedenko SV, Lutsik IO, Matyushin AA, Polozkov SD, Shmakov VM, Modestov DG, Prikhodko VV, Arzhannikov AV (2023) Fusion-fission hybrid reactor facility: power profiling. Nuclear Energy and Technology 9(1): 65-70. https://doi.org/10.3897/nucet.9.102781

Author

Bedenko, Sergey V., primary, Lutsik, Igor O., additional, Matyushin, Anton A., additional, Polozkov, Sergey D., additional, Shmakov, Vladimir M., additional, Modestov, Dmitry G., additional, Prikhodko, Vadim V., additional, and Arzhannikov, Andrey V., additional

Published

2023

28. Fusion-fission hybrid reactor facility: power profiling

Author

Bedenko, Sergey V., primary, Lutsik, Igor O., additional, Matyushin, Anton A., additional, Polozkov, Sergey D., additional, Shmakov, Vladimir M., additional, Modestov, Dmitry G., additional, Prikhodko, Vadim V., additional, and Arzhannikov, Andrey V., additional

Published

2023

29. Analytical and Technological Research Center “High Technologies & Nanostructured Materials”: History, Formation and Achieved Results

Author

Geydt, P. V., primary, Arzhannikov, A. V., additional, Aseev, A. L., additional, Shklyaev, A. A., additional, Volodin, V. A., additional, Azarov, I. A., additional, Zaikovskii, V. I., additional, Utkin, D. E., additional, Larichev, Yu. V., additional, Chepkasov, S. Y., additional, and Kuznetsov, S. A., additional

Published

2022

30. Investigation of the Increment of Transverse Instability of a Kiloampere Electron Beam in a Linear Induction Accelerator for Its Use in a Terahertz FEL

Author

Sandalov, E. S., primary, Sinitsky, S. L., additional, Skovorodin, D. I., additional, Arzhannikov, A. V., additional, Logachev, P. V., additional, Bak, P. A., additional, Zhivankov, K. I., additional, Nikiforov, D. A., additional, Petrenko, A. V., additional, Ginzburg, N. S., additional, Peskov, N. Yu., additional, and Protas, R. V., additional

Published

2022

31. Energy Content and Spectral Composition of a Submillimeter Radiation Flux Generated by a High-Current Electron Beam in a Plasma Column With Density Gradients

Author

Arzhannikov, Andrey V., primary, Sinitsky, Stanislav L., additional, Popov, Sergei S., additional, Timofeev, Igor V., additional, Samtsov, Denis A., additional, Sandalov, Evgeny S., additional, Kalinin, Petr V., additional, Kuklin, Konstantin N., additional, Makarov, Maksim A., additional, Rovenskikh, Andrey F., additional, Stepanov, Vasilii D., additional, Annenkov, Vladimir V., additional, and Glinsky, Vladimir V., additional

Published

2022

32. Electrodynamic System of a Powerful THz Band Free Electron Laser Based on the LIU Linear Induction Accelerator: Modeling and Cold Tests.

Author

Peskov, N. Yu., Arzhannikov, A. V., Belousov, V. I., Ginzburg, N. S., Zaslavsky, V. Yu., Nikiforov, D. A., Oparina, Yu. S., Savilov, A. V., Sandalov, E. S., Sinitsky, S. L., and Sobolev, D. I.

Abstract

The authors describe the current stage of the development of a powerful long-pulse free electron laser (FEL) of the terahertz band at the Budker Institute of Nuclear Physics in cooperation with Institute of Applied Physics on the basis of the LIU induction accelerator with an energy of 5–10 MeV, a current of up to 2 kA, and a pulse duration of up to 200 ns. It is proposed that two alternative types of electrodynamic systems may be used to ensure a regime of stable narrow band generation: advanced Bragg resonators and quasi-optical resonators of the Talbot type. FEL parameters calculated on the basis of these resonators are presented, along with results from modeling under conditions of substantial oversize. The operability of the new types of resonators is verified in cold electrodynamic tests. [ABSTRACT FROM AUTHOR]

Published

2023

33. Kiloampere Electron Beam of a Linear Induction Accelerator as a Driver for a Submillimeter Free Electron Laser.

Author

Sandalov, E. S., Sinitsky, S. L., Arzhannikov, A. V., Nikiforov, D. A., Skovorodin, D. I., Pavlyuchenko, V. A., Ginzburg, N. S., Peskov, N. Yu., Protas, R. V., and Karasev, D. Yu.

Abstract

A project for a submillimeter free electron laser (FEL) based on a relativistic electron beam (REB) generated in a linear induction accelerator (LIA) is proposed for the Budker Institute of Nuclear Physics, Siberian Branch, Russian Academy of Sciences, and the Institute of Applied Physics, Russian Academy of Sciences. A theoretical analysis shows that the electron beam generated in the LIA (energy MeV, current kA, normalized emittance ~ 1100 π mm mrad) is a suitable driver for generating subgigawatt pulses of coherent EM radiation in the submillimeter range of wavelengths (0.3–1 THz). The main proposals for developing a FEL based on the electron beam generated in a linear induction accelerator are presented, the main project tasks are outlined, and proposed ways of solving them are described. Results from electron-optical experiments on the formation of an electron beam intended for FEL applications are presented. [ABSTRACT FROM AUTHOR]

Published

2023

34. Plasma system of the GOL-3T facility

Author

Arzhannikov, A. V., Burdakov, A. V., Burmasov, V. S., Ivanov, I. A., Kuznetsov, S. A., Kuklin, K. N., Mekler, K. I., Polosatkin, S. V., Postupaev, V. V., Rovenskikh, A. F., Sinitsky, S. L., and Sklyarov, V. F.

Published

2015

35. Recent Results on Development of Sub-GW Long-pulse THz-band FEL

Author

Peskov, N. Yu., primary, Arzhannikov, A. V., additional, Bak, P. A., additional, Belousov, V. I., additional, Ginzburg, N. S., additional, Nikiforov, D. A., additional, Sandalov, E. S., additional, Sinitsky, S. L., additional, Sobolev, D. I., additional, Starostenko, A. A., additional, Zaslavsky, V. Yu., additional, and Zhivankov, K. I., additional

Published

2022

36. Oversized Electrodynamic Systems for Powerful Long-Pulse Sub-THz/THz Band FEL: Simulations and “Cold” Tests

Author

Peskov, Nikolai Yu., primary, Belousov, Vladimir I., additional, Ginzburg, Naum S., additional, Oparina, Yuliya S., additional, Savilov, Andrey V., additional, Sobolev, Dmitry I., additional, Zaslavsky, Vladislav Yu., additional, Arzhannikov, Andrey V., additional, Nikiforov, Danila A., additional, Sandalov, Evgeny S., additional, and Sinitsky, Stanislav L., additional

Published

2022

37. Department of Plasma Physics of the Physics Department at Novosibirsk State University

Author

Annenkov, V. V., primary, Arzhannikov, A. V., additional, Bagryansky, P. A., additional, Beklemishev, A. D., additional, Davydenko, V. I., additional, Sinitsky, S. L., additional, Skovorodin, D. I., additional, Sudnikov, A. V., additional, Chernoshtanov, I. S., additional, Fedorenkov, E. A., additional, and Shoshin, A. A., additional

Published

2022

38. Design of a Narrowband Filter for Implementing the Undersamping Method in Terahertz Time-Domain Spectrometers

Author

Rybak, A. A., primary, Kuznetsov, S. А., additional, Arzhannikov, A. V., additional, and Nikolaev, N. A., additional

Published

2022

39. Figure 7 from: Bedenko SV, Lutsik IO, Matyushin AA, Polozkov SD, Shmakov VM, Modestov DG, Prikhodko VV, Arzhannikov AV (2022) Fusion-fission hybrid reactor facility: neutronic research. Nuclear Energy and Technology 8(1): 25-30. https://doi.org/10.3897/nucet.8.82294

Author

Bedenko, Sergey V., primary, Lutsik, Igor O., additional, Matyushin, Anton A., additional, Polozkov, Sergey D., additional, Shmakov, Vladimir M., additional, Modestov, Dmitry G., additional, Prikhodko, Vadim V., additional, and Arzhannikov, Andrey V., additional

Published

2022

40. Figure 2 from: Bedenko SV, Lutsik IO, Matyushin AA, Polozkov SD, Shmakov VM, Modestov DG, Prikhodko VV, Arzhannikov AV (2022) Fusion-fission hybrid reactor facility: neutronic research. Nuclear Energy and Technology 8(1): 25-30. https://doi.org/10.3897/nucet.8.82294

Author

Bedenko, Sergey V., primary, Lutsik, Igor O., additional, Matyushin, Anton A., additional, Polozkov, Sergey D., additional, Shmakov, Vladimir M., additional, Modestov, Dmitry G., additional, Prikhodko, Vadim V., additional, and Arzhannikov, Andrey V., additional

Published

2022

41. Figure 5 from: Bedenko SV, Lutsik IO, Matyushin AA, Polozkov SD, Shmakov VM, Modestov DG, Prikhodko VV, Arzhannikov AV (2022) Fusion-fission hybrid reactor facility: neutronic research. Nuclear Energy and Technology 8(1): 25-30. https://doi.org/10.3897/nucet.8.82294

Author

Bedenko, Sergey V., primary, Lutsik, Igor O., additional, Matyushin, Anton A., additional, Polozkov, Sergey D., additional, Shmakov, Vladimir M., additional, Modestov, Dmitry G., additional, Prikhodko, Vadim V., additional, and Arzhannikov, Andrey V., additional

Published

2022

42. Figure 3 from: Bedenko SV, Lutsik IO, Matyushin AA, Polozkov SD, Shmakov VM, Modestov DG, Prikhodko VV, Arzhannikov AV (2022) Fusion-fission hybrid reactor facility: neutronic research. Nuclear Energy and Technology 8(1): 25-30. https://doi.org/10.3897/nucet.8.82294

Author

Bedenko, Sergey V., primary, Lutsik, Igor O., additional, Matyushin, Anton A., additional, Polozkov, Sergey D., additional, Shmakov, Vladimir M., additional, Modestov, Dmitry G., additional, Prikhodko, Vadim V., additional, and Arzhannikov, Andrey V., additional

Published

2022

43. Fusion-fission hybrid reactor facility: neutronic research

Author

Bedenko, Sergey V., primary, Lutsik, Igor O., additional, Matyushin, Anton A., additional, Polozkov, Sergey D., additional, Shmakov, Vladimir M., additional, Modestov, Dmitry G., additional, Prikhodko, Vadim V., additional, and Arzhannikov, Andrey V., additional

Published

2022

44. Figure 6 from: Bedenko SV, Lutsik IO, Matyushin AA, Polozkov SD, Shmakov VM, Modestov DG, Prikhodko VV, Arzhannikov AV (2022) Fusion-fission hybrid reactor facility: neutronic research. Nuclear Energy and Technology 8(1): 25-30. https://doi.org/10.3897/nucet.8.82294

Author

Bedenko, Sergey V., primary, Lutsik, Igor O., additional, Matyushin, Anton A., additional, Polozkov, Sergey D., additional, Shmakov, Vladimir M., additional, Modestov, Dmitry G., additional, Prikhodko, Vadim V., additional, and Arzhannikov, Andrey V., additional

Published

2022

45. Figure 4 from: Bedenko SV, Lutsik IO, Matyushin AA, Polozkov SD, Shmakov VM, Modestov DG, Prikhodko VV, Arzhannikov AV (2022) Fusion-fission hybrid reactor facility: neutronic research. Nuclear Energy and Technology 8(1): 25-30. https://doi.org/10.3897/nucet.8.82294

Author

Bedenko, Sergey V., primary, Lutsik, Igor O., additional, Matyushin, Anton A., additional, Polozkov, Sergey D., additional, Shmakov, Vladimir M., additional, Modestov, Dmitry G., additional, Prikhodko, Vadim V., additional, and Arzhannikov, Andrey V., additional

Published

2022

46. Figure 1 from: Bedenko SV, Lutsik IO, Matyushin AA, Polozkov SD, Shmakov VM, Modestov DG, Prikhodko VV, Arzhannikov AV (2022) Fusion-fission hybrid reactor facility: neutronic research. Nuclear Energy and Technology 8(1): 25-30. https://doi.org/10.3897/nucet.8.82294

Author

Bedenko, Sergey V., primary, Lutsik, Igor O., additional, Matyushin, Anton A., additional, Polozkov, Sergey D., additional, Shmakov, Vladimir M., additional, Modestov, Dmitry G., additional, Prikhodko, Vadim V., additional, and Arzhannikov, Andrey V., additional

Published

2022

47. Development of Powerful Spatially Extended W-Band Cherenkov Maser of Planar Geometry With Two-Dimensional Distributed Feedback

Author

Arzhannikov, Andrey V., primary, Ginzburg, Naum S., additional, Kalinin, Peter V., additional, Malkin, Andrey M., additional, Martyanov, Ivan V., additional, Peskov, Nikolai Yu., additional, Samtsov, Denis A., additional, Sandalov, Evgeny S., additional, Sergeev, Alexander S., additional, Sinitsky, Stanislav L., additional, Stepanov, Vasily D., additional, Vikharev, Alexander A., additional, and Zaslavsky, Vladislav Yu., additional

Published

2022

48. Powerful Cherenkov Masers with 2D Slow-wave Structures of Planar and Cylindrical Geometry

Author

Peskov, N. Yu., primary, Abubakirov, E. B., additional, Arzhannikov, A. V., additional, Denisenko, A. N., additional, Ginzburg, N. S., additional, Kalinin, P. V., additional, Sandalov, E. S., additional, Sinitsky, S. L., additional, Stepanov, V. D., additional, Vikharev, A. A., additional, and Zaslavsky, V. Yu., additional

Published

2021

49. Generation of a Directed Flux of Megawatt THz Radiation as a Result of Strong REB-Plasma Interaction in a Plasma Column

Author

Samtsov, Denis A., primary, Arzhannikov, Andrey V., additional, Sinitsky, Stanislav L., additional, Makarov, Maksim A., additional, Kuznetsov, Sergei A., additional, Kuklin, Konstantin N., additional, Popov, Sergei S., additional, Sandalov, Evgeny S., additional, Rovenskikh, Andrey F., additional, Kasatov, Alexandr A., additional, Stepanov, Vasiliy D., additional, Ivanov, Ivan A., additional, Timofeev, Igor V., additional, Annenkov, Vladimir V., additional, and Glinskiy, Vladimir V., additional

Published

2021

50. A traveling-wave ring resonator with Bragg deflectors in a two-stage terahertz free-electron laser

Author

Arzhannikov, A. V., Ginzburg, N. S., Denisov, G. G., Kalinin, P. V., Peskov, N. Yu., Sergeev, A. S., and Sinitskii, S. L.

Published

2014