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Information × Registration Number 2120U000756, Article popup.category Книга Title Dynamics of self-sustained plasma-beam discharge at high energy density (AI translated) popup.author Гречко Ярослав ОлеговичHrechko Ya.O.Hrechko Yaroslav OlehovychHrechko Ya.O. popup.publication 01-01-2020 popup.source_user Харківський національний університет імені В. Н. Каразіна popup.source https://ekhnuir.karazin.ua/handle/123456789/15929 popup.publisher Харків : Харківський національний університет імені В.Н. Каразіна Description Hrechko Ya.O. Dynamics of self-sustained plasma-beam discharge at high energy density. – Manuscript. Thesis for a Candidate Degree in Physics and Mathematics, Specialty 01.04.08 – Plasma Physics. – V. N. Karazin Kharkiv National University of the Ministry of Education and Science of Ukraine. – Kharkiv, 2020. The thesis is devoted to the experimental and theoretical study of the formation conditions and dynamics of the self-sustained plasma-beam discharge at high energy density in the high-current pulsed plasma diode of low pressure. The design feature of this plasma diode is the limitation of the high-voltage electrode working surface. This made it possible to concentrate high current density (up to 2 MA/cm2) on high-voltage electrode and promoted the formation of the space charge double layer near its working surface. In order to evaluate the efficiency of energy input into the plasma, a method for calculating the active power of a high-current pulsed discharge is provided. The dynamics of the discharge active power has been calculated based on the dynamics of the discharge current using the discharge circuit equation of a high-current pulsed discharge. The calculations did not take into account all the active power, but only that which is caused by charged particles beams accelerated in the double layer. The double layer is responsible for the local energy input into the discharge, due to the powerful collective dissipative mechanism of energy transfer from the electron beam to the plasma. popup.nrat_date 2026-04-13 Close