Patent Number: 
Section: claims

1. A plasma confinement system comprising:an inner electrode;an intermediate electrode that at least partially surrounds the inner electrode; andan outer electrode that at least partially surrounds the intermediate electrode, the outer electrode comprising:a solid conductive shell comprising:a solid conductive outer shell; anda solid inner shell that is disposed within the solid conductive outer shell and in contact with the solid conductive outer shell,wherein the solid inner shell comprises:an axial wall that at least partially encircles a longitudinal axis of the plasma confinement system; anda radial wall that couples the axial wall to the solid conductive outer shell,wherein the radial wall and a first end of the outer electrode form a pool region,an electrically conductive material disposed on the solid conductive shell, wherein the electrically conductive material has a melting point within a range of 180° C. to 800° C. at 1 atmosphere of pressure; anda pumping system configured to circulate the electrically conductive material over the outer electrode when the electrically conductive material is in a liquid state. 2. The plasma confinement system of claim 1, further comprising a feeding mechanism that is configured to move the inner electrode along the longitudinal axis of the plasma confinement system. 3. The plasma confinement system of claim 1, further comprising a cooling system that is configured to cool the inner electrode during operation of the plasma confinement system. 4. The plasma confinement system of claim 1, further comprising:a first power supply configured to apply a voltage between the inner electrode and the intermediate electrode; anda second power supply configured to apply a voltage between the inner electrode and the outer electrode. 5. The plasma confinement system of claim 1, wherein the electrically conductive material comprises one or more of lithium, lead, or tin. 6. The plasma confinement system of claim 1, the inner electrode having a first end that is at least partially surrounded by the outer electrode, wherein the plasma confinement system is configured to maintain a Z-pinch plasma between the first end of the inner electrode and the electrically conductive material. 7. The plasma confinement system of claim 1,further comprising:a heat exchanger; anda first port configured to guide the electrically conductive material from the heat exchanger into the pool region. 8. The plasma confinement system of claim 1, wherein the pumping system is configured to circulate the electrically conductive material such that movement of the electrically conductive material includes one or more of an azimuthal component or an axial component with respect to the longitudinal axis of the plasma confinement system. 9. The plasma confinement system of claim 1, a first end of the inner electrode being formed of graphite or carbon fiber. 10. The plasma confinement system of claim 1, further comprising one or more gas ports configured to direct gas into an acceleration region between the inner electrode and the intermediate electrode. 11. The plasma confinement system of claim 1, wherein the plasma confinement system allows current to flow between the inner electrode and the outer electrode through both a Z-pinch plasma and the electrically conductive material. 12. The plasma confinement system of claim 1, the inner electrode having a first end that is at least partially surrounded by the outer electrode. 13. The plasma confinement system of claim 12, wherein the first end of the inner electrode is rounded. 14. The plasma confinement system of claim 1, further comprising an insulator between a second end of the outer electrode and the intermediate electrode. 15. The plasma confinement system of claim 14, wherein the plasma confinement system is configured to maintain a Z-pinch plasma between a first end of the inner electrode and the electrically conductive material on the longitudinal axis of the plasma confinement system. 16. The plasma confinement system of claim 15, wherein the Z-pinch plasma has axial flow that varies in a radial direction. 17. The plasma confinement system of claim 7, the axial wall comprising an end that faces a second end of the outer electrode, the plasma confinement system further comprising:a first pump configured to move the electrically conductive material from the pool region to a region that is outside the axial wall and separated from the pool region by the radial wall. 18. The plasma confinement system of claim 17, the plasma confinement system further comprising:a second pump configured to move the electrically conductive material from the pool region to the region that is outside the axial wall and separated from the pool region by the radial wall. 19. The plasma confinement system of claim 1, wherein the intermediate electrode forms a cavity and the inner electrode is positioned at least partially within the cavity. 20. The plasma confinement system of claim 19, the inner electrode having a first end that is at least partially surrounded by the outer electrode.