Patent Number: 
Section: claims

1. A nuclear radiation generator capable of downhole operation comprising:a charged particle source;a target material configured to generate nuclear radiation when struck by charged particles from the charged particle source; andan acceleration column between the charged particle source and the target material, having a longitudinal axis and an insulator surface, that includes a plurality of electrodes configured to draw a beam of the charged particles from the charged particle source to strike the target material, the plurality of electrodes comprising an extractor electrode, a suppressor electrode, and an intermediate electrode between the extractor electrode and the suppressor electrode;wherein each of the extractor electrode, suppressor electrode, and intermediate electrode comprising a first end coupled to the insulator surface, a second end extending toward the longitudinal axis of the acceleration column, and an intermediate portion between the first end and the second end;a distance between the second end of the extractor electrode and the second end of the intermediate electrode being equal to a distance between the second end of the intermediate electrode and the second end of the suppressor electrode. 2. The nuclear radiation generator of claim 1, wherein the charged particle source comprises a cathode configured to emit electrons and the target material comprises an anode configured to emit x-rays when struck by electrons from the cathode. 3. The nuclear radiation generator of claim 1, wherein the charged particle source comprises an ion source configured to emit ions and the target material comprises a target electrode configured to emit neutrons when struck by ions from the ion source. 4. A neutron generator capable of downhole operation comprising:an ion source;a target electrode; andan acceleration column between the ion source and the target electrode, said acceleration column having a longitudinal axis and an insulator surface, wherein the acceleration column includes a plurality of electrodes configured to draw ions from the ion source toward the target electrode, the plurality of electrodes comprising an extractor electrode, a suppressor electrode, and an intermediate electrode between the extractor electrode and the suppressor electrode;wherein each of the extractor electrode, suppressor electrode, and intermediate electrode comprising a first end coupled to the insulator surface, a second end extending toward the longitudinal axis of the acceleration column, and an intermediate portion between the first end and the second end;a distance between the second end of the extractor electrode and the second end of the intermediate electrode being equal to a distance between the second end of the intermediate electrode and the second end of the suppressor electrode. 5. The neutron generator of claim 4, wherein the plurality of electrodes includes an extractor electrode, a suppressor electrode, and a plurality of intermediate electrodes between the extractor electrode and the suppressor electrode. 6. The neutron generator of claim 4, wherein the plurality of electrodes is configured such that electrical field stresses on any of the plurality of electrodes are less than approximately 250 kV/cm when a voltage potential applied across the plurality of electrodes is greater than or equal to approximately 100 kV. 7. The neutron generator of claim 4, wherein the neutron generator is configured to apply a voltage potential across the plurality of electrodes of greater than or equal to approximately 100 kV during operation. 8. The neutron generator of claim 4, wherein the neutron generator is configured to apply a voltage potential across the plurality of electrodes of greater than or equal to approximately 150 kV during operation. 9. The neutron generator of claim 4, wherein the acceleration column is maintained at a pressure during operation. 10. A neutron generator capable of downhole operation comprising:an ion source;a target electrode; andan acceleration column having a longitudinal axis and an insulator surface and disposed between the ion source and the target electrode, comprising:an extractor electrode nearer to the ion source than the target electrode;a suppressor electrode nearer to the target electrode than the ion source; andan intermediate electrode disposed between the extractor electrode and the suppressor electrode;wherein each of the extractor electrode, suppressor electrode, and intermediate electrode comprising a first end coupled to the insulator surface, a second end extending toward a longitudinal axis of the acceleration column, and an intermediate portion between the first end and the second end;a distance between the second end of the extractor electrode and the second end of the intermediate electrode being equal to a distance between the second end of the intermediate electrode and the second end of the suppressor electrode, the second end of the intermediate electrode being curved inwardly toward, but not crossing, the longitudinal axis of the acceleration column. 11. The neutron generator of claim 10, wherein the extractor electrode is configured to guide ions from the ion source toward the target electrode without striking the suppressor electrode under downhole operation. 12. The neutron generator of claim 10, wherein the extractor electrode, the intermediate electrode, and the suppressor electrode are electrically separated from one another by the insulator forming the insulator surface, wherein the insulator is a high voltage insulator configured to insulate voltages of 50 kV, and wherein the intermediate electrode is disposed in the high voltage insulator approximately midway between a point at which the extractor electrode is disposed in the high voltage insulator and a point at which the suppressor electrode is disposed in the high voltage insulator. 13. The neutron generator of claim 10, wherein the extractor electrode, the intermediate electrode, and the suppressor electrode extend into the acceleration column through a high voltage insulator configured to insulate voltages of 50 kV, wherein the intermediate electrode is disposed in the high voltage insulator farther from the ion source than a second end of the suppressor electrode. 14. The neutron generator of claim 10, wherein the intermediate electrode has a voltage potential approximately midway between a voltage potential of the extractor electrode and a voltage potential of the suppressor electrode. 15. The neutron generator of claim 10, wherein the intermediate electrode is one of a plurality of intermediate electrodes disposed between the extractor electrode and the suppressor electrode. 16. The neutron generator of claim 15, wherein at least one of the plurality of intermediate electrodes has a voltage potential between a voltage potential of the extractor electrode and a voltage potential of the suppressor electrode. 17. A neutron generator capable of downhole operation, comprising:an ion source;a target electrode; andan acceleration column having a longitudinal axis and an insulator surface and disposed between the ion source and the target electrode;wherein the acceleration column comprises at least three electrodes disposed between the ion source and the target electrode, a first of the at least three electrodes being adjacent to a second of the at least three electrodes, and the second of the at least three electrodes being adjacent to a third of the at least three electrodes;wherein the at least three electrodes include an extractor electrode and a suppressor electrode;wherein each electrode of the at least three electrodes comprises a first end coupled to the insulator surface, a second end extending toward the longitudinal axis of the acceleration column, and an intermediate portion between the first end and the second end;wherein a distance between the second ends of each adjacent electrode of the at least three electrodes is equal to each other;wherein the second end of at least one electrode of the at least three electrodes is curved inwardly toward, but not crossing, the longitudinal axis of the acceleration column; andwherein the neutron generator is configured to apply a voltage potential between one of the at least three electrodes and another of the at least three electrodes of greater than approximately 100 kV during operation. 18. The neutron generator of claim 17, wherein the neutron generator is configured to apply a voltage potential between one electrode of the at least three electrodes and another electrode of the at least three electrodes of greater than approximately 150 kV during operation. 19. The neutron generator of claim 17, comprising two high voltage power supplies coupled respectively one electrode of the at least three electrodes and another electrode of the at least three electrodes, and wherein the two high voltage power supplies are configured to supply the voltage potential during the operation. 20. The neutron generator of claim 17, wherein the at least three electrodes comprises an intermediate electrode, wherein the intermediate electrode is connected to ground. 21. The neutron generator of claim 20, comprising a pressure housing and a vacuum envelope, wherein the pressure housing surrounds the vacuum envelope and wherein the vacuum envelope surrounds the ion source, the target electrode, and the acceleration column, and wherein the intermediate electrode is configured to mechanically secure the vacuum envelope to the pressure housing. 22. The neutron generator of claim 17, wherein the at least three electrodes are configured to keep a maximum electrical field stress on the at least three electrodes less than or equal to approximately 140 kV/cm during operation.