Mathematical Aspects of Modelling Oscillations and Wake Waves in Plasma
Auteur : Chizhonkov E.V.
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.
Free plasma oscillations. Introductory Information. Planar one-dimensional non-relativistic oscillations (P1NE-equations). Planar one-dimensional relativistic oscillations (P1RE-equations). Cylindrical one-dimensional oscillations (equations C1RE and C1NE). Influence of ion dynamics (P1EI-equations). Planar two-dimensional relativistic oscillations (P2RE-equations). Plasma wake waves. Preliminary information. Numerical Algorithms for the Basic Task. Additional Studies. Literature.
E.V. Chizhonkov, Lomonosov Moscow State University, Moscow, RU
Date de parution : 12-2021
15.6x23.4 cm
Date de parution : 04-2019
15.6x23.4 cm
Thèmes de Mathematical Aspects of Modelling Oscillations and Wake... :
Mots-clés :
Ordinary Differential Equations; NUMA; Finite Difference Method; Cauchy Problem; Perturbation Theory Method; Lagrangian Variables; Axial Solution; Eulerian Variables; Wake Wave; Lagrangian Coordinate; Plasma Oscillations; Electron Density; Artificial Boundary Conditions; Time Layer; Electron Density Function; Laser Pulse; Underdense Plasma; Maximum Electron Density; Riemann Problem; Multiple Excess; Tridiagonal Matrix Algorithm; Smooth Classical Solution; Eulerian Coordinates; Laser Plasma Interactions; Circular Symmetry