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Electrothermal (ET) plasma discharges have application to mass acceleration technologies relevant to military ballistics and magnetic confinement fusion reactor operation. ET plasma discharges are initiated in capillary geometries by passing large currents (order of tens of kiloamperes) along the capillary axis. A partially ionized plasma then forms and radiates heat to the capillary walls inducing...
Electrothermal (ET) plasma discharges have captured the interest of researchers due to their wide range of applicability. They have been investigated for their application to solid propellant ignition, electric propulsion, high heat flux experiments, and fusion fuel pellet injection. ET plasma discharges involve the passage of high currents (order of tens of kA) through narrow channels (usually millimeters...
Electrothermal (ET) plasma discharges are arc-driven, capillary discharges that draw currents up to several tens of kA. These discharges have radii on the order of millimeters and lengths on the order of centimeters. They have a breadth of applicability ranging from materials processing to pellet injection for deep fusion fueling.
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