Add to ORKGIn our attempt to find analytical solutions for breakdown waves, we employ a set of three-component fluid equations. In addition to reporting the method of integration of electron fluid dynamical equations through the dynamical transition region (sheath region), the wave profile for ionization rate, electron number density and electron temperature inside the sheath will be discussed. Also, the effect of the current on electron temperature, electron number density and ionization rate will be reported
Considering the electrons as the main element in breakdown wave propagation and using a one-dimensio...
For analytical solution of breakdown waves with a large current behind the wave front, we employ a o...
Breakdown waves propagating in the opposite direction of the applied electric field force are referr...
A three component, one-dimensional, constant velocity, steady-state fluid model is employed to descr...
This paper describes our numerical investigation into ionizing breakdown waves, primarily antiforce ...
In this paper we describe numerical investigations of breakdown waves concentrating on antiforce wav...
The propagation of breakdown waves in a gas, which is primarily driven by electron gas pressure, is ...
The propagation of breakdown waves in a gas, which is primarily driven by electron gas pressure, is ...
In our investigation of breakdown waves, we apply a one-dimensional, three-component, steady-state f...
In the theoretical investigation of the electrical breakdown of a gas, we apply a one-dimensional, s...
Recently, the initial boundary conditions for proforce waves with a substantial current behind the s...
For fluid dynamical analysis of breakdown waves, we employ a one-dimensional, three-component (elect...
In our investigation of breakdown waves, we use a one-dimensional, steady-state, constant velocity f...
In our investigation of breakdown waves, we use a one-dimensional, steady-state, constant velocity f...
The electron gas in electric discharge can be described by a set of one-dimensional fluid dynamical ...
Considering the electrons as the main element in breakdown wave propagation and using a one-dimensio...
For analytical solution of breakdown waves with a large current behind the wave front, we employ a o...
Breakdown waves propagating in the opposite direction of the applied electric field force are referr...
A three component, one-dimensional, constant velocity, steady-state fluid model is employed to descr...
This paper describes our numerical investigation into ionizing breakdown waves, primarily antiforce ...
In this paper we describe numerical investigations of breakdown waves concentrating on antiforce wav...
The propagation of breakdown waves in a gas, which is primarily driven by electron gas pressure, is ...
The propagation of breakdown waves in a gas, which is primarily driven by electron gas pressure, is ...
In our investigation of breakdown waves, we apply a one-dimensional, three-component, steady-state f...
In the theoretical investigation of the electrical breakdown of a gas, we apply a one-dimensional, s...
Recently, the initial boundary conditions for proforce waves with a substantial current behind the s...
For fluid dynamical analysis of breakdown waves, we employ a one-dimensional, three-component (elect...
In our investigation of breakdown waves, we use a one-dimensional, steady-state, constant velocity f...
In our investigation of breakdown waves, we use a one-dimensional, steady-state, constant velocity f...
The electron gas in electric discharge can be described by a set of one-dimensional fluid dynamical ...
Considering the electrons as the main element in breakdown wave propagation and using a one-dimensio...
For analytical solution of breakdown waves with a large current behind the wave front, we employ a o...
Breakdown waves propagating in the opposite direction of the applied electric field force are referr...