Персона: Терехов, Святослав Алексеевич
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Институт физико-техничеcких интеллектуальных систем
Институт физико-технических интеллектуальных систем впервые в стране обеспечивает комплексную подготовку специалистов по созданию киберфизических устройств и систем самого различного назначения – основного вида технических устройств середины 21 века. ИФТИС реализует «дуальную» модель образования, в рамках которой направляет студентов на стажировку и выпускников для трудоустройства на передовые предприятия, занятые созданием инновационных киберфизических продуктов, в первую очередь, на предприятия ГК «Росатом». Основным индустриальным партнером ИФТИС является ведущее предприятие ГК «Росатом» — ФГУП «ВНИИА им. Н.Л. Духова».
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- ПубликацияТолько метаданныеAcceleration of Macroscopic Clusters in Crossed Magnetic Fields(2019) Karimov, AlexanderR.; Shikanov, AlexanderE.; Murad, PaulA.; Terekhov, SvyatoslavA.; Каримов, Александр Рашатович; Шиканов, Александр Евгеньевич; Терехов, Святослав АлексеевичThe acceleration of rotating plasma flow in crossed magnetic fields produced momentum transfer between the macroscopic degrees of freedom for a plasma flow was investigated. Results implied a concept for acceleration of plasma flow containing the charged macroscopic particles. Here, the case is treated when the plasma flow consists of electrons, protons, and heavy, multiply charged negative dust particles only. The analysis shows that these charged macroscopic particles have been trapped and, then, accelerated in the main plasma flow. As a result, such complex plasma flow can be accelerated in one axial direction to increase the thrust. It suggests that such complex plasma flow produced, for example, from cosmic dust medium may be used as a propellant and a work body for plasma thrusters.
- ПубликацияТолько метаданныеAcceleration of Dusty Plasma Flow in Azimuthal Electric and Radial Magnetic Fields(2020) Karimov, A. R.; Terekhov, S. A.; Shikanov, A. E.; Каримов, Александр Рашатович; Терехов, Святослав Алексеевич; Шиканов, Александр Евгеньевич© 2020, Pleiades Publishing, Ltd.Abstract: In the framework of the model of cold hydrodynamics, acceleration of the flow of dusty plasma in azimuthal electric and radial magnetic fields has been studied. The obtained results show that there are conditions under which macroscopic particles are captured and accelerated by the plasma flow.
- ПубликацияТолько метаданныеUse of Plasma Flows to Clean the Near-Earth Space(2021) Yamshchikov, V. A.; Karimov, A. R.; Terekhov, S. A.; Shikanov, A. E.; Каримов, Александр Рашатович; Терехов, Святослав Алексеевич; Шиканов, Александр Евгеньевич© 2021, Pleiades Publishing, Ltd.Abstract: A system for cleaning near-Earth space from space debris in the upper layers of the atmosphere is proposed, which is based on a plasma accelerator that uses the medium of the upper layers of the atmosphere and solar radiation to generate plasma flows of the required intensity. Estimates of the main material and energy characteristics of the system were obtained, which demonstrate the feasibility of the proposed device.
- ПубликацияТолько метаданныеElectrophysical Means in Space Research and Applications for the near-Earth Space(2021) Murad, P. A.; Yamschikov, V.; Karimov, A. R.; Terekhov, S. A.; Каримов, Александр Рашатович; Терехов, Святослав Алексеевич© 2021, American Institute of Aeronautics and Astronautics Inc.. All rights reserved.The paper discusses the use of the interplanetary substance as a possible fuel for spacecraft’s plasma thrusters for interplanetary flights and the possibility of creation the electrodynamic space debris collection system in the upper atmosphere based on a plasma propulsor using the upper atmosphere medium and solar radiation to create plasma flows of the required intensity. The intensity is such that the debris is used for propellant as well as storage of the space debris. Moreover, the device would use a magnetic field to convert linear momentum of the debris into angular momentum for capture. Estimates of the basic material and energy characteristics of this state-of-the art system are obtained, which demonstrate the technical feasibility of the proposed device. Furthermore, the accelerator may also use plasma with motion of some of the debris as propellant.