Patent Number: 
Section: claims

1. An ion acceleration device, comprising:an inner electrode formed of a plasma;an outer electrode surrounding the inner plasma electrode;a vacuum chamber surrounding the inner electrode;a source for supplying ions between the inner plasma electrode and the outer electrode; anda means for creating a potential between the inner plasma electrode and the outer electrode to accelerate ions towards the inner plasma electrode;wherein the plasma is created by forming a high voltage potential between a first electrode and a second electrode positioned within the outer electrode or by focusing a radio frequency source within the vacuum. 2. The ion acceleration device of claim 1, wherein the inner electrode is formed by a high voltage potential created between a first electrode and a second electrode. 3. The ion acceleration device of claim 1, wherein the outer electrode forms at least part of the vacuum chamber. 4. The ion acceleration device of claim 1 wherein the source for supplying ions is a gas source which supplies a gas between the inner electrode and the outer electrode which is ionized in situ when the potential is created between the inner plasma electrode and the outer electrode. 5. The ion acceleration device as in either claim 1 wherein the inner electrode is formed by focusing a radio frequency emission on an ionizable gas. 6. The ion acceleration device of claim 1, wherein the source for supplying ions is an ion gun. 7. An inertial electrostatic confinement fusion device, comprising:an inner electrode formed of a plasma;an outer electrode surrounding the inner plasma electrode;a vacuum chamber surrounding the inner plasma electrode;a source for supplying ions into the vacuum chamber; anda means for creating a potential between the inner plasma electrode and the outer electrode to accelerate ions towards the inner plasma electrode;wherein the plasma is created by forming a high voltage potential between a first electrode and a second electrode positioned within the outer electrode or by focusing a radio frequency source within the vacuum. 8. The inertial electrostatic confinement fusion device of claim 7, wherein the inner plasma electrode is formed by a high voltage potential created between a first electrode and a second electrode. 9. The inertial electrostatic confinement fusion device of claim 7, wherein the outer electrode forms at least part of the vacuum chamber. 10. The inertial electrostatic confinement fusion device of claim 7, wherein the source for supplying ions is a gas source which supplies a gas between the inner electrode and the outer electrode which is ionized in situ when a potential is created between the inner plasma electrode and the outer electrode. 11. The inertial electrostatic confinement fusion device of claim 7, wherein inner electrode is formed by focusing a radio frequency emission on an ionizable gas. 12. The inertial electrostatic confinement fusion device of claim 7, wherein the gas source is a deuterium gas source. 13. The inertial electrostatic confinement fusion device of claim 7, wherein the source for supplying ions is an ion gun. 14. A method of accelerating ions comprising:forming a vacuum;creating a plasma within the vacuum;surrounding the plasma with an outer electrode;providing an ion source between the plasma and the outer electrode; andforming a potential between the plasma and the outer electrode to accelerate ions from the ion source towards the plasma;wherein the plasma is created by forming a high voltage potential between a first electrode and a second electrode positioned within the outer electrode or by focusing a radio frequency source within the vacuum. 15. A method of producing a nuclear reaction comprising:forming a vacuum;creating a plasma within the vacuum;surrounding the plasma with an outer electrode;forming a potential between the inner and outer electrodes; and providing ions that are effected by the potential between the inner and outer electrodes so as to accelerate the ions towards the inner electrode resulting in collisions of the ions with other particles creating a nuclear fusion reaction;wherein the plasma is created by forming a high voltage potential between a first electrode and a second electrode positioned within the outer electrode or by focusing a radio frequency source within the vacuum. 16. The method of claim 14, wherein the ions are provided by providing a supplied gas between the plasma and the outer electrode. 17. The method of claim 15, wherein the ions are provided by supplying a deuterium gas.