Introduction to Simulation Methods for Gas Discharge Plasmas

Accuracy, reliability and limitations

By (author) Ismail Rafatov, Anatoly Kudryavtsev

Publication date:

07 December 2020

Length of book:

120 pages

Publisher

Institute Of Physics Publishing

Dimensions:

254x178mm
7x10"

ISBN-13: 9780750323581

Gas discharge plasma is the most common type of low-temperature plasma, with a large number of practical applications covering almost all areas of modern science and technology. This book is an introduction to the numerical modeling methods for gas discharge plasmas. It is intended to assist and direct graduate students and junior researchers, whose research activity deals with computational plasma physics. Topics covered include the essentials of basic modelling approaches (particle, fluid, and hybrid) for gas discharges, and the implementation of these methods with examples of glow (DC and RF) discharges. Numerical studies of nonlinear dynamics and formation of spatio-temporal patterns in gas discharge systems are also presented.

Key Features

  • Focuses solely on gas discharge plasmas
  • Covers basic modelling techniques, including particle, fluid, and hybrid
  • Provides details of applications and implementation for the considered methods
  • Special emphasis is given to the applicability and reliability of different modelling techniques
  • Provides specific examples of numerical simulations of the gas discharge plasmas

If you model low pressure (non-thermal) plasmas, this book will provide the fundamental equations that can be used to simulate various aspects of the low-pressure plasma. You will also learn about the physics behind the equations through explanations and graphical plots of results including comparisons between simulations and experimental results. The reader would need a background in plasma physics and some familiarity with Boltzmann’s equation to fully appreciate this book.

John J Shea IEEE Electrical Engineering Magazine, May June 2021 Vol. 37

If you model low pressure (non-thermal) plasmas, this book will provide the fundamental equations that can be used to simulate various aspects of the low-pressure plasma. You will also learn about the physics behind the equations through explanations and graphical plots of results including comparisons between simulations and experimental results. The reader would need a background in plasma physics and some familiarity with Boltzmann’s equation to fully appreciate this book.

John J Shea IEEE Electrical Engineering Magazine, May June 2021 Vol. 37