Patent Number: 
Section: claims

1. A system for applying synchronous x-ray pulses to inertial confinement fusion target material, comprising:a) a central target chamber for receiving fusion target material in the form of a fusion target pellet in spherical form;wherein the target chamber is bound by a chamber wall;b) a plurality of energy drivers arranged around the exterior of the target chamber in symmetrical pairs about said fusion target pellet and arranged in a 3-dimensionally symmetric, direct drive configuration about said fusion target pellet;c) means for controlling the plurality of energy drivers to:generate x-ray pulses exterior of the chamber wall,emit the generated x-ray pulses into the target chamber, andapply the emitted x-ray pulses as combined synchronous x-ray pulses directly into the fusion target pellet in the target chamber,wherein each of the synchronous x-ray pulses includes one x-ray pulse from each of the energy drivers; andd) a plurality of means for extracting fusion reaction energy released from the fusion target pellet, comprising both:i) means to extract high voltage DC energy from fusion plasma involving the fusion target pellet; andii) means to extract thermal energy from the target chamber;e) each of the plurality of energy drivers comprising an x-ray source, wherein each x-ray source comprises:i) a cylindrical triode electron tube,wherein each electron tube includes a hollow central anode along a center axis of the tube,wherein each electron tube includes a grid and a cathode radially spaced from the anode;ii) wherein the cathode and the grid form a circular waveguide electron gun that produces a wave of ground potential in Transverse Electric Mode when the grid is grounded,which wave propagates along a linear axis of the electron gun at the speed of light;the cathode and the grid being configured to cause a radially symmetrical collapsing travelling wave of electrons to be formed when the grid is grounded;said wave of electrons propagating along the linear axis of the electron gun,sweeping along the anode at the speed of light, andhaving energy capable of causing electrons to penetrate a wall of the anode and cause a zone of Bremsstrahlung and electrons,wherein said zone is swept as a wavefront along an inner hollow space of the anode at the speed of light;iii) wherein the inner hollow space is filled with a lasing medium which is fully ionized by the swept zone; andiv) wherein the energy of the swept zone is pumped in a linear fashion by at least energy contained in distributed interelectrode capacitance of the cathode and the grid. 2. The system of claim 1, wherein each of the plurality of energy drivers comprises a unitary apparatus that produces both:an x-ray pulse for causing the release of fusion reaction energy from the target material; andRF energy to heat the fusion target material. 3. The system of claim 1, further comprising:an apodizing structure associated with each of the plurality of energy drivers for reshaping the wavefront of the x-ray pulse to be concave from the perspective of the fusion target material;the apodizing structure defined by either one of:an apodizing filter comprising a solid object of varying thickness along the direction of the x-ray pulse; the thickness of the apodizing filter being greater near the center of the wavefront of the x-ray pulse than near the edges of said wavefront; ora diffractive optical component. 4. The system of claim 2, further comprising:an apodizing structure associated with each of the plurality of energy drivers for reshaping the wavefront of the x-ray pulse to be concave from the perspective of the fusion target material;the anodizing structure defined by either one of:an anodizing filter comprising a solid object of varying thickness along the direction of the x-ray pulse; the thickness of the anodizing filter being greater near the center of the wavefront of the x-ray pulse than near the edges of said wavefront; ora diffractive optical component. 5. The system of claim 1, 2 or 3, wherein said plurality of energy drivers are powered by an energy storage means; said energy storage means receiving power from:a first power supply providing start-up and make-up power; anda second power supply deriving energy from high voltage DC energy extracted from said fusion reaction energy;wherein said start-up power is the total energy required for initiating the release of fusion reaction energy and the make-up power is the energy that is added to the energy from the second power supply to maintain the release of fusion reaction energy. 6. The system of claim 1, wherein each of the plurality of energy drivers uses x-ray source gas of any one of, or combination of Oxygen, Nitrogen, Neon, Argon, Krypton, Radon, Bismuth, Mercury and Uranium. 7. The system of claim 1, 2 or 3, wherein each of the plurality of energy drivers has an x-ray drive energy between about 200 electron Volts and 100 KiloElectron Volts. 8. The system of claim 1, 2 or 3, wherein each of the plurality of energy drivers uses a lasing medium of any one of, or combination of, any element with an atomic number between 7 and 93. 9. The system of claim 1, further comprising a coaxial capacitor concentrically wound on the external surface of the cathode. 10. The system of claim 1, wherein:the x-ray source also produces a high voltage pulse at the output end of the anode; andsaid high voltage pulse is used to produce an RF heating pulse for heating the fusion target material by RF generation means comprising a resonant cavity and electron gun being attached to the output end of the anode of the x-ray source so as to produce a phase coherent burst of RF energy coincident with the x-ray pulse. 11. The system of claim 5, wherein said first power supply uses an Electron-Coupled Transformer to generate a high voltage pulse compatible with, and added to, the power generated by said second power supply. 12. The system of claim 10, wherein RF generation means of each of the plurality of energy drivers comprises a Virtual Cathode Oscillator with a central aperture in the cathode of the electron gun, the central aperture allowing an x-ray pulse to pass through the cathode of the electron gun of the Virtual Cathode Oscillator. 13. The system of claim 10, wherein RF generation means of each of the plurality of energy drivers incorporates a cylindrical drift tube forming a Magnetically Insulated Linear Oscillator with a central aperture in the cathode of the electron gun which allows an x-ray pulse to pass through the cathode of the electron gun of the Magnetically insulated Linear Oscillator. 14. The system of claim 12 or 13, wherein the RF generation means is automatically sequentially triggered after the onset of the x-ray pulse by internal interconnective elements of the energy driver. 15. The system of claim 12, wherein:the drift tube has a periodic grating geometry on the inner surface of said tube;spacing, face angle, and geometry of the grating and the energy of an incident electron beam are determinants of the RF output frequency spectrum of the Magnetically Insulated Linear Oscillator; andthe energy of the incident electron beam is greater than 100,000 electron Volts. 16. The system of claim 3, wherein the apodizing structure is defined by an apodizing filter comprising a solid object of varying thickness along the direction of the x-ray pulse; the thickness of the apodizing filter being greater near the center of the wavefront of the x-ray pulse than near the edges of said wavefront. 17. The system of claim 1, wherein the target chamber contains pulsed magnetic confinement coils for keeping the plasma from contacting an innermost-facing surface of an innermost-facing structure in the target chamber, said coils being responsive to an output of a pulse modulator synchronized with an output of a pulse modulator supplying high voltage DC power to said plurality of energy drivers. 18. The system of claim 2, wherein all of said energy drivers are located external to the target chamber. 19. A method for applying synchronous X-ray pulses to inertial confinement fusion target material, comprising:a) providing a central target chamber for receiving fusion target material in the form of a fusion target pellet in spherical form;wherein the target chamber is bound by a chamber wall;b) arranging a plurality of energy drivers around the exterior of the target chamber in symmetrical pairs about said fusion target pellet and in a 3-dimensionally symmetric, direct drive configuration about said fusion target pellet;c) controlling the plurality of energy drivers so that they:generate x-ray pulses exterior of the chamber wall,emit the generated x-ray pulses into the target chamber, andapply the emitted x-ray pulses as combined synchronous x-ray pulses directly in the fusion target pellet in the target chamber,wherein each of the synchronous x-ray pulses includes one x-ray pulse from each of the energy drivers; andd) providing a plurality of means for extracting fusion reaction energy released from the fusion target pellet, comprising both:i) providing means to extract high voltage DC energy from fusion plasma involving the fusion target pellet; andii) providing means to extract thermal energy from the target chamber,e) wherein each of the plurality of energy drivers comprises an x-ray source, wherein each x-ray source comprises:i) a cylindrical triode electron tube,wherein each electron tube includes a hollow central anode along a center axis of the tube,wherein each electron tube includes a grid and a cathode radially spaced from the anode;ii) wherein the cathode and the grid form a circular waveguide electron gun that produces a wave of ground potential in Transverse Electric Mode when the grid is grounded,which wave propagates along a linear axis of the electron gun at the speed of light;the cathode and the grid being configured to cause a radially symmetrical collapsing travelling wave of electrons to be formed when the grid is grounded;said wave of electrons propagating along the linear axis of the electron gun,sweeping along the anode at the speed of light, andhaving energy capable of causing electrons to penetrate as wall of the anode and cause a zone of Bremsstrahlung and electrons,wherein said zone is swept as a wavefront along an inner hollow space of the anode at the speed of light;iii) wherein the inner hollow space is filled with a lasing medium which is fully ionized by the swept zone; andiv) wherein the energy of the swept zone is pumped in a linear fashion by at least energy contained in distributed interelectrode capacitance of the cathode and the grid. 20. The method of claim 19, further comprising, reshaping the wavefront of the x-ray pulse to be concave from the perspective of the fusion target material by means of an apodizing structure defined as either one of a diffractive optical component or an apodizing filter comprising a solid object of varying thickness along the direction of the x-ray pulse; the thickness of the apodizing filter being greater near the center of the wavefront of the x-ray pulse than near the edges of said wavefront. 21. The method of claim 20, wherein the reshaping the wavefront of the x-ray pulse to be concave from the perspective of the fusion target material is by means of an apodizing structure defined as an apodizing filter comprising a solid object of varying thickness along the direction of the x-ray pulse; the thickness of the apodizing filter being greater near the center of the wavefront of the x-ray pulse than near the edges of said wavefront.