Add to ORKGAbstract. The main advances made within the Ignitor program, that is aimed at investigating the physics of fusion burning plasmas at or close to ignition, are described. In particular, the operation of the machine in the H and I regimes at the 10 MA plasma current levels has been considered and analyzed. The unique properties of the plasmas that can be generated by operating the machine with reduced parameters (lower magnetic fields and plasma currents) relative to those needed to achieve ignition are identified. A key feature of this operation is the relatively fast duty cycle that can be maintained. The Ideal Ignition Conditions, under which the density barrier due to bremsstrahlung emission in high density plasmas is removed, can be atta...
The physics requirements of the heating and current (H&CD) systems in a Demonstration Fusion Power P...
FIRE is a compact, high field tokamak being studied as an option for the next step in the US magneti...
The next major frontier in magnetic fusion physics is to explore and understand the strong nonlinear...
The main advances made within the Ignitor program, that is aimed at investigating the physics of fus...
The Ignitor Program maintains the objective of approaching D-T ignition conditions by incorporating ...
Thermonuclear ignition condition for deuterium-tritium plasmas can be achieved in compact, high magn...
Careful analyses of the parameter evolution of the plasmas that can be produced by the Ignitor machi...
One of the main physics objectives of ITER is to operate, in a nuclear environment and on sufficient...
The concept for a single-turn tokamak experiment IGNITEX 1 makes possible the realization of a contr...
A recently proposed fusion testing device called IGNITEX is described in this paper. The original id...
Fusion energy holds the key to a new source of energy in the future with limitless sustainability fu...
The Ignitor project is aimed at approaching ignition conditions in Deuterium-Tritium plasmas in ord...
This report describes work done on the Compact Ignition Tokamak (CIT), both at the Princeton Plasma ...
The buming plasma regime will exhibit a number of complex phenomena that must be studied and underst...
The Fast Ignitor is an alternate approach to ICF in which short pulse lasers are used to initiate bu...
The physics requirements of the heating and current (H&CD) systems in a Demonstration Fusion Power P...
FIRE is a compact, high field tokamak being studied as an option for the next step in the US magneti...
The next major frontier in magnetic fusion physics is to explore and understand the strong nonlinear...
The main advances made within the Ignitor program, that is aimed at investigating the physics of fus...
The Ignitor Program maintains the objective of approaching D-T ignition conditions by incorporating ...
Thermonuclear ignition condition for deuterium-tritium plasmas can be achieved in compact, high magn...
Careful analyses of the parameter evolution of the plasmas that can be produced by the Ignitor machi...
One of the main physics objectives of ITER is to operate, in a nuclear environment and on sufficient...
The concept for a single-turn tokamak experiment IGNITEX 1 makes possible the realization of a contr...
A recently proposed fusion testing device called IGNITEX is described in this paper. The original id...
Fusion energy holds the key to a new source of energy in the future with limitless sustainability fu...
The Ignitor project is aimed at approaching ignition conditions in Deuterium-Tritium plasmas in ord...
This report describes work done on the Compact Ignition Tokamak (CIT), both at the Princeton Plasma ...
The buming plasma regime will exhibit a number of complex phenomena that must be studied and underst...
The Fast Ignitor is an alternate approach to ICF in which short pulse lasers are used to initiate bu...
The physics requirements of the heating and current (H&CD) systems in a Demonstration Fusion Power P...
FIRE is a compact, high field tokamak being studied as an option for the next step in the US magneti...
The next major frontier in magnetic fusion physics is to explore and understand the strong nonlinear...