Patent Number: 
Section: claims

1. An apparatus for moderation of positrons, the apparatus comprising:a vacuum chamber;at least one cathode structure positioned within the vacuum chamber;a moderator material attached to at least a portion of the at least one cathode structure, wherein the moderator material is configured to receive positrons from a positron source;at least one anode positioned within the vacuum chamber and spaced apart from the at least one cathode structure and moderator material so as to define a vacuum gap between the moderator material and the at least one anode; anda voltage source connected to the at least one cathode structure and the at least one anode, wherein the voltage source is configured to apply a positive potential to the at least one cathode structure and a negative potential to the at least one anode to create an electric field that is configured to cause the positrons received by the moderator material to drift toward a surface of the moderator material and into a vacuum gap. 2. The apparatus according to claim 1 further comprising a magnetic field source configured to produce a magnetic field across throughout the at least one cathode structure and the at least one anode, wherein the magnetic field is perpendicular to the electric field and is configured to cooperate with the electric field to encourage the positrons to drift through the vacuum gap toward a harvesting area. 3. The apparatus according to claim 1 further comprising an electron source, wherein the positron source comprises a converter positioned within the vacuum chamber proximate the at least one cathode structure, wherein the electron source is configured to emit electrons toward the converter, wherein the converter is configured to produce positrons upon collision of the electrons with the converter. 4. The apparatus according to claim 1 further comprising a neutron source configured to emit neutrons toward the at least one cathode structure, wherein the at least one cathode structure is configured to emit gamma-rays upon capture of the neutrons by the at least one cathode structure, and wherein the at least one anode is configured to produce positrons upon collision of the gamma-rays with the at least one anode such that the at least one anode acts as the positron source. 5. The apparatus according to claim 1, wherein the at least one cathode structure comprises at least two cathode structures, wherein the at least one anode comprises at least two anodes, and wherein the at least two cathode structures and the at least two anodes are positioned along a plane so as to form a planar array. 6. The apparatus according to claim 1, wherein the at least one cathode structure defines a cylindrical shape, wherein the at least one anode comprises four anodes spaced radially from the at least one cathode structure, wherein each of the anodes defines a cylindrical shape. 7. The apparatus according to claim 1, wherein the at least one cathode structure defines a cylindrical shape, wherein the at least one anode comprises eight anodes spaced radially from the at least one cathode structure, wherein each of the anodes defines a cylindrical shape. 8. The apparatus according to claim 1, wherein the at least one cathode structure comprises a cathode and an insulator material positioned between the moderator material and the cathode, wherein the insulator material is configured to increase electrical resistance between the cathode and the moderator material. 9. An apparatus for moderation of positrons, the apparatus comprising:a vacuum chamber;at least one cathode structure positioned within the vacuum chamber;a moderator material attached to at least a portion of the at least one cathode structure, wherein the moderator material is configured to receive positrons from a positron source;at least one anode positioned within the vacuum chamber;a voltage source connected to the at least one cathode structure and the at least one anode, wherein the voltage source is configured to apply a positive potential to the at least one cathode structure and a negative potential to the at least one anode to create an electric field that is configured to cause the positrons received by the moderator material to drift toward a surface of the moderator material; anda magnetic field source configured to produce a magnetic field throughout the at least one cathode structure and the at least one anode, wherein the magnetic field is perpendicular to the electric field and configured to cooperate with the electric field to encourage the positrons to drift toward a harvesting area. 10. The apparatus according to claim 9, wherein the at least one anode is spaced apart from the at least one cathode structure so as to define a vacuum gap between the moderator material and the at least one anode, wherein the magnetic field is configured to cooperate with the electric field to cause the positrons to drift through the vacuum gap toward the harvesting area. 11. The apparatus according to claim 9 further comprising an electron source, wherein the positron sources comprises a converter positioned within the vacuum chamber proximate the at least one cathode structure, wherein the electron source is configured to emit electrons toward the converter, wherein the converter is configured to produce positrons upon collision of the electrons with the converter. 12. The apparatus according to claim 9 further comprising a neutron source configured to emit neutrons toward the at least one cathode structure, wherein the at least one cathode structure is configured to emit gamma-rays upon capture of the neutrons by the at least one cathode structure, and wherein the at least one anode is configured to produce positrons upon collision of the gamma-rays with the at least one anode such that the at least one anode acts as a positron source. 13. The apparatus according to claim 9, wherein the at least one cathode structure comprises at least two cathode structures, wherein the at least one anode comprises at least two anodes, and wherein the at least two cathode structures and the at least two anodes are positioned along a plane so as to form a planar array. 14. The apparatus according to claim 9, wherein the at least one cathode structure defines a cylindrical shape, wherein the at least one anode comprises four anodes spaced radially from the at least one cathode structure, wherein each of the anodes defines a cylindrical shape. 15. The apparatus according to claim 9, wherein the at least one cathode structure defines a cylindrical shape, wherein the at least one anode comprises eight anodes spaced radially from the at least one cathode structure, wherein each of the anodes defines a cylindrical shape. 16. The apparatus according to claim 9, wherein the at least one cathode structure comprises a cathode and an insulator material positioned between the moderator material and the cathode, wherein the insulator material is configured to increase electrical resistance between the cathode and the moderator material. 17. A method for moderation of positrons, the method comprising:providing an apparatus comprising:a vacuum chamber;at least one cathode structure positioned within the vacuum chamber;a moderator material attached to at least a portion of the at least one cathode structure, wherein the moderator material is configured to receive positrons from a positron source;at least one anode positioned within the vacuum chamber and spaced apart from the at least one cathode structure and moderator material so as to define a vacuum gap between the moderator material and the at least one anode; anda voltage source connected to the at least one cathode structure and the at least one anode;establishing an electric field across the apparatus by applying a positive potential to the at least one cathode structure and applying a negative potential to the at least one anode, wherein the electric field is configured to cause the positrons received by the moderator material to drift toward a surface of the moderator material and into the vacuum gap; andextracting the positrons that drift away from the moderator material through the vacuum gap. 18. The method of claim 17 further comprising establishing a magnetic field throughout the at least one cathode structure and the at least one anode, wherein the magnetic field is perpendicular to the electric field and configured to cooperate with the electric field to encourage the positrons to drift through the vacuum gap toward a harvesting area. 19. The method according to claim 17 further comprising causing emission of electrons toward the positron source, wherein the positron source comprises a converter positioned within the vacuum chamber proximate the at least one cathode structure, wherein the converter is configured to produce positrons upon collision of the electrons with the converter. 20. The method according to claim 17 further comprising causing emission of neutrons toward the at least one cathode structure, wherein the at least one cathode structure is configured to emit gamma-rays upon capture of the neutrons by the at least one cathode structure, and wherein the at least one anode is configured to produce positrons upon collision of the gamma-rays with the at least one anode such that the anode acts as the positron source. 21. A method for moderation of positrons, the method comprising:providing an apparatus comprising:a vacuum chamber;at least one cathode structure positioned within the vacuum chamber;a moderator material attached to at least a portion of the at least one cathode structure, wherein the moderator material is configured to receive positrons from a positron source;at least one anode positioned within the vacuum chamber; anda voltage source connected to the at least one cathode structure and the at least one anode;establishing an electric field across the apparatus by applying a positive potential to the at least one cathode structure and applying a negative potential to the at least one anode, wherein the electric field is configured to cause the positrons received by the moderator material to drift toward a surface of the moderator material;establishing a magnetic field throughout the at least one cathode structure and the at least one anode, wherein the magnetic field is perpendicular to the electric field and is configured to cooperate with the electric field to encourage the positrons to drift toward a harvesting area; andextracting the positrons from the harvesting area. 22. The method of claim 21, wherein the at least one anode is spaced apart from the at least one cathode structure so as to define a vacuum gap between the moderator material and the at least one anode, and wherein the magnetic field is configured to cooperate with the electric field to cause the positrons to drift through the vacuum gap toward the harvesting area. 23. The method according to claim 21 further comprising causing emission of electrons toward the positron source, wherein the positron source comprises a converter positioned within the vacuum chamber proximate the at least one cathode structure, wherein the converter is configured to produce positrons upon collision of the electrons with the converter. 24. The method according to claim 21 further comprising causing emission of neutrons toward the at least one cathode structure, wherein the at least one cathode structure is configured to emit gamma-rays upon capture of the neutrons by the at least one cathode structure, and wherein the at least one anode is configured to produce positrons upon collision of the gamma-rays with the at least one anode such that the anode acts as the positron source.