Mathematical modelling of oscillations and wake waves in plasma / E.V. Chizhonkov.
Material type:
TextPublisher: Boca Raton : CRC Press, Taylor & Francis Group, 2019Description: 1 online resourceContent type: text Media type: computer Carrier type: online resourceISBN: 9780429288289; 042928828X; 9781000012194; 1000012190; 9781000018714; 1000018717; 9781000005370; 1000005372Subject(s): Plasma oscillations -- Mathematical models | Plasma waves -- Mathematical models | Oscillations -- Mathematical models | Plasma (Ionized gases) | SCIENCE / Energy | SCIENCE / Mechanics / General | SCIENCE / Physics / General | SCIENCE / Chemistry / General | SCIENCE / Mathematical Physics | SCIENCE / PhysicsDDC classification: 530.4/4015118 LOC classification: QC718.5.W3 | C4878 2019ebOnline resources: Taylor & Francis | OCLC metadata license agreement Summary: This book is devoted to research in the actual field of mathematical modeling in modern problems of plasma physics associated with vibrations and wake waves excited by a short high-power laser pulse. The author explores the hydrodynamic model of the wake wave in detail and from different points of view, within the framework of its regular propagation, a development suitable for accelerating electrons, and the final tipping effect resulting in unregulated energy transfer to plasma particles. Key selling features: Presents research directly related to the propagation of super-power short laser pulses (subject of the 2018 Nobel Prize in Physics). Presents mathematical modeling of plasma physics associated with vibrations and wake waves excited by a short high-power laser pulse. Includes studies of large-amplitude plasma oscillations. Most of the presented results are of original nature and have not appeared in the domestic and foreign scientific literature Written at a level accessible for researchers, academia, and engineers.
This book is devoted to research in the actual field of mathematical modeling in modern problems of plasma physics associated with vibrations and wake waves excited by a short high-power laser pulse. The author explores the hydrodynamic model of the wake wave in detail and from different points of view, within the framework of its regular propagation, a development suitable for accelerating electrons, and the final tipping effect resulting in unregulated energy transfer to plasma particles. Key selling features: Presents research directly related to the propagation of super-power short laser pulses (subject of the 2018 Nobel Prize in Physics). Presents mathematical modeling of plasma physics associated with vibrations and wake waves excited by a short high-power laser pulse. Includes studies of large-amplitude plasma oscillations. Most of the presented results are of original nature and have not appeared in the domestic and foreign scientific literature Written at a level accessible for researchers, academia, and engineers.
OCLC-licensed vendor bibliographic record.