Shi Nguyen-Kuok - Professor, Doctor of Technical Sciences, Academician of the Russian Academy of Electrical Sciences, Head of Laboratory of Plasma Physics of National Research University "Moscow Power Engineering Institute", Supervisor of Ltd "Technokeramika".

Experience of scientific and pedagogical work of Shi Nguyen-Kuok is 22 years, including experience of pedagogical work. Shi Nguyen-Kuok prepared 6 PhD students. Currently, the supervisor of 1 PhD graduate student.

Currently, Shi Nguyen-Kuok has 135 publications, including 7 textbooks used in a teaching practice. Shi Nguyen-Kuok developed a theoretical framework for the study of plasma and plasma processes in electrotechnological RF and Arc plasma torches. For the first time he has developed a method of structural modeling of plasma and plasma torches, heat and mass transfer processes and computational procedures allowing to identify the relationship between internal and external (technological and structural) parameters of plasma torches; determine the optimal regime of their agreement with the sources of supply; determine the complex physical processes in RF and Arc plasma torches, their internal and external parameters, heat and mass transfer processes in the plasma jet, near electrode processes, the processes of heat transfer and flow dynamics of solid particles in the plasma, etc.; solve the problems of analysis and structural and parametric synthesis of plasma electrotechnological installations. He developed the theoretical basis of mathematical modeling of electrotechnological plasma processes used in the preparation of lecture courses.

In 2006 Shi Nguyen-Kuok received a grant from the President of the Russian Federation "Conducting research by young scientists."

In 2012 was awarded by the first place in the competition of manuscripts of scientific literature NRU "MPEI" and received a grant for the publication of a scientific monograph "Basics of mathematical modeling of Low temperature plasma."

In 2013 by led of Shi Nguyen-Kuok, RF plasma installation of high power 1000 kW/0.44 MHz for the treatment of refractory particles and for test mode heating materials in the plasma jet, was prepared and released in work (Obninsk, LTD "Technokeramika").

Shi Nguyen-Kuok is a full member of the Russian Academy of Electrical Sciences (from 2015) and the International Academy for System Studies (since 2012).

Foreword.

Chapter 1 Basic mathematical models of Low-temperature plasma.
1.1 The main approaches to the theoretical description of the plasma. 1.2 The model of equilibrium plasma. 1.3 The two-temperature model of non-equilibrium plasma. 1.4 The two-speed model of the plasma. 1.5 The gas-dynamic models of plasma turbulence. 1.6 The models of the light emission and absorption by the plasma.

Chapter 2 Classical calculation of particle interaction cross sections.
2.1 The classical problem of particles scattering. 2.2 Determination of the interaction cross sections of the plasma particles.

Chapter 3 The quantum-mechanical description of the particles scattering theory.
3.1 The Schrodinger equation. 3.2 Solution of the Schrodinger equation for the elastic interactions. 3.3 Determination of phase shift and scattering amplitude. 3.4 The Born approximation to calculate the amplitudes of the scattered waves. 3.5 Determination of the differential and total cross sections of elastic interactions.

Chapter 4 Determination of the composition, thermodynamic properties and plasma transport coefficients on the basis of the model of particles mean free path.
4.1 The plasma composition. 4.2 Thermodynamic properties of the plasma. 4.3 Transport coefficients of the plasma. 4.4 Three-body recombination and impact ionization coefficients. 4.5 The frequency of particles collisions, the current density and power when the plasma is heated.

Chapter 5 The solution of the kinetic Boltzmann equation and calculation of the transport coefficients of the plasma.
5.1 Derivation of the kinetic Boltzmann equation. 5.2 The transport equations. 5.3 Solution of the kinetic Boltzmann equation by the Chapman - Enskog approach. 5.4 Determination of the viscosity 5.5 Determination the coefficients of diffusion, thermal diffusion and thermal conductivity. 5.6 Determination of the electrical conductivity.

Chapter 6 Numerical methods of plasma physics.
6.1. The computational methods and basic mathematical algorithms. 6.2. Stability of the difference schemes and computational procedures. 6.3 Organization of the computational procedures.

Chapter 7 Simulation and calculation of paramete of RF-plasma torches.
7.1 Main characteristics of the induction plasma and RF-plasma torches. 7.2 Calculation of the electromagnetic field in RF-plasma torches. 7.3 Simulation of the equilibrium plasma in RF-plasma torches. 7.4 Disturbance of the thermal and ionization equilibrium in plasma, caused by the gases movement. 7.5 Simulation of non-equilibrium plasma in RF-plasma torches.

Chapter 8 Simulation and calculation of parameters in Arc plasma torches.
8.1 Features of electric arc. 8.2 Electric arc in the channel for plasma cutting and spraying. 8.3 Simulation of electric arcs in the channel. 8.4 Two-dimensional electromagnetic problem for the electric arc. 8.5 Simulation of the free open arc.

Chapter 9 The calculation of the near-electrode processes in Arc plasma torches.
9.1 Model of the near-cathode processes. 9.2 Calculation of the near-cathode region. 9.3 Thermal problem of the cathode heating. 9.4 Model of the anode processes.

Chapter 10 Calculation of the heat transfer and movement of the solid particles in the plasma torches.
10.1 The heat exchange and movement of the particles in the plasma stream. 10.2 Calculation of the particles motion and heating with the given parameters of the plasma flow. 10.3 The model of plasma, "loaded" with a stream of solid particles.

Chapter 11 Features of the experimental methods and automated diagnostic systems of RF and Arc plasma torches.
11.1 The experimental setup and diagnostic system for the study of induction and arc plasma torches. 11.2 The main methods of plasma diagnostics and plasma torches. 11.3 Measurements of plasma parameters in the induction and arc plasma torches.

Appendix.

This book offers the reader an overview of the basic approaches to the theoretical description of low-temperature plasmas, covering numerical methods, mathematical models and modeling techniques. The main methods of calculating the cross sections of plasma particle interaction and the solution of the kinetic Boltzmann equation for determining the transport coefficients of the plasma are also presented. The results of calculations of thermodynamic properties, transport coefficients, the equilibrium particle-interaction cross sections and two-temperature plasmas are also discussed. Later chapters consider applications, and the results of simulation and calculation of plasma parameters in induction and arc plasma torches are presented. The complex physical processes in high-frequency plasmas and arc plasmas, the internal and external parameters of plasma torches, near-electrode processes, heat transfer, the flow of solid particles in plasmas and other phenomena are considered. The book is intended for professionals involved in the theoretical study of low-temperature plasmas and the design of plasma torches, and will be useful for advanced students in related areas.