Electrostatic accelerated-recirculating-ion fusion neutron/proton source

US 20030223528A1
Filed: 02/12/2003
Published: 12/04/2003
Est. Priority Date: 06/16/1995
Status: Abandoned Application

First Claim

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1. An electrostatic accelerated-recirculating-ion fusion neutron/proton source, comprising:

a substantially cylindrical, axially elongated hollow vacuum chamber having an inner and outer wall;

a first cylindrical reflector and a second cylindrical reflector, said first and second reflectors having concave surfaces facing the longitudinal center of said axially elongated hollow vacuum chamber and disposed at and adjacent to opposite ends of said axially elongated vacuum chamber so that their centers lie on the axis of said vacuum chamber;

a hollow cylindrical cathode that is 100% transparent to oscillating ions and electrons within said vacuum chamber between said first and second reflectors, said cathode defining a central volume and having the same axis as said vacuum chamber;

a first hollow cylindrical anode and a second hollow cylindrical anode, said first and second anodes being 100% transparent to oscillating ions and electrons, said first anode disposed between said first reflector and said cathode and said second anode disposed between said second reflector and said cathode, where said first and second anodes have axes coincident with the axis of said vacuum chamber;

a nuclear fusible gas in said vacuum chamber wherein fusion reactions caused by collisions of ions produce neutrons and/or protons; and

means for applying an electric potential between said first and second anodes, said cathode and said first and second reflectors to produce ions and electrons from the nuclear fusible gas within said central volume, said cathode, anodes and reflectors functioning to electrostatically focus (i) said ions in a line-type fusion reaction region along the axis of the hollow cathode and (ii) said electrons in first and second electron collision-induced ionization regions within said first and second anodes, respectively, wherein said ions and electrons oscillate back and forth along the axial direction of said vacuum chamber within the volume defined by the inside diameter of the central cathode and bounded on the ends by said first and second reflectors, said reflectors electrostatically reflect electrons escaping through said anodes and electrostatically refocus said electrons in a volume along the axis inside said anodes, and further wherein said oscillating ions and electrons aggregate into preferred paths in the background gas thereby reducing losses of ions and electrons due to transverse diversion of ions and electrons to the electrodes.

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Abstract

An electrostatic accelerated-recirculating-ion fusion neutron/proton source is disclosed. The device acts as a compact accelerator-plasma-target fusion neutron/proton source which can emulate a line-type source. The unit comprises an axially elongated hollow vacuum chamber having an inner and outer wall. Reflectors are located at opposite ends of the vacuum chamber so that their centers lie on the axis of the vacuum chamber. A cathode that is 100% transparent to oscillating particles is located within the vacuum chamber between the reflectors, defining a central volume and having the same axis as the vacuum chamber. Anodes that are 100% transparent to oscillating particles are located near opposite ends of the vacuum chamber between the reflectors dishes and the cathode, having axes coincident with the axis of the vacuum chamber. A means is also provided for introducing controlled amounts of reactive gas into the vacuum chamber, and its central volume. Further, a means is provided for applying an electric potential between said anodes and said cathode and said reflectors. This applied potential plus the electrode/reflector designs/spacings are such that ions are focused in a zone along the axis of the hollow cathode, creating a line-like neutron/proton source. Electrons are focused within the hollow anodes, creating the primary ion source there, while leaking electrons are reflected and refocused within the anodes by the concave reflector dishes. In an alternative embodiment, a means for generating a magnetic field in the axial direction is attached to the circumference of the vacuum chamber. The magnetic field enhances electrostatic confinement and focusing effects such as to reduce ion/electron diffusion losses and increase the fusion rate density in the reaction zone in the hollow cathode.

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39 Claims

1. An electrostatic accelerated-recirculating-ion fusion neutron/proton source, comprising:
- a substantially cylindrical, axially elongated hollow vacuum chamber having an inner and outer wall;
  
  a first cylindrical reflector and a second cylindrical reflector, said first and second reflectors having concave surfaces facing the longitudinal center of said axially elongated hollow vacuum chamber and disposed at and adjacent to opposite ends of said axially elongated vacuum chamber so that their centers lie on the axis of said vacuum chamber;
  
  a hollow cylindrical cathode that is 100% transparent to oscillating ions and electrons within said vacuum chamber between said first and second reflectors, said cathode defining a central volume and having the same axis as said vacuum chamber;
  
  a first hollow cylindrical anode and a second hollow cylindrical anode, said first and second anodes being 100% transparent to oscillating ions and electrons, said first anode disposed between said first reflector and said cathode and said second anode disposed between said second reflector and said cathode, where said first and second anodes have axes coincident with the axis of said vacuum chamber;
  
  a nuclear fusible gas in said vacuum chamber wherein fusion reactions caused by collisions of ions produce neutrons and/or protons; and
  
  means for applying an electric potential between said first and second anodes, said cathode and said first and second reflectors to produce ions and electrons from the nuclear fusible gas within said central volume, said cathode, anodes and reflectors functioning to electrostatically focus (i) said ions in a line-type fusion reaction region along the axis of the hollow cathode and (ii) said electrons in first and second electron collision-induced ionization regions within said first and second anodes, respectively, wherein said ions and electrons oscillate back and forth along the axial direction of said vacuum chamber within the volume defined by the inside diameter of the central cathode and bounded on the ends by said first and second reflectors, said reflectors electrostatically reflect electrons escaping through said anodes and electrostatically refocus said electrons in a volume along the axis inside said anodes, and further wherein said oscillating ions and electrons aggregate into preferred paths in the background gas thereby reducing losses of ions and electrons due to transverse diversion of ions and electrons to the electrodes.
- View Dependent Claims (2)
- - 2. The neutron/proton source of claim 1, wherein said cathode is a thin walled, electrically conducting cylinder.

3. An electrostatic accelerated-recirculating-ion fusion neutron/proton source, comprising:
- an axially elongated cylindrical vacuum chamber having an inner and outer wall;
  
  first and second concave reflecting dishes, said first and second reflecting dishes disposed at and adjacent to opposite ends of said axially elongated vacuum chamber so that their concave surfaces face the center of said vacuum chamber and their centers lie on the axis of said vacuum chamber;
  
  a cylindrical, solid, hollow cathode disposed within said vacuum chamber between said first and second reflecting dishes, wherein said cathode is 100% transparent to oscillating ions and electrons, defines a central volume and has the same axis as said vacuum chamber;
  
  first and second cylindrical, hollow anodes that are 100% transparent to oscillating ions and electrons, wherein said first anode is disposed within said vacuum chamber between said first reflecting dish and said cathode, said second anode is disposed within said vacuum chamber between said second reflecting dish and said cathode, and said first and second anodes have axes coincident with the axis of said vacuum chamber;
  
  a nuclear fusible gas in said vacuum chamber wherein fusion reactions caused by collisions between ions produce energetic fusion reaction products including neutrons and/or protons; and
  
  means for applying an electric potential between said first and second anodes, said cathode and said first and second reflecting dishes to produce ions and electrons from the nuclear fusible gas within said central volume and to electrostatically focus said ions and electrons in regions along the axes of the cathode and anodes, respectively, said regions defined by the length-to-diameter ratios for the cathode and anodes and the spacing between the between the cathode and anodes, wherein said ions and electrons oscillate back and forth along the axial direction of said vacuum chamber within the volume defined by the inside diameter of the central cathode and bounded on the ends by said first and second reflectors, said reflectors electrostatically reflecting and refocusing electrons in a volume along the axis inside said anodes, and further wherein said oscillating ions and electrons aggregate into preferred paths in the background gas thereby reducing losses of ions and electrons due to transverse diversion of ions and electrons to the electrodes.
- View Dependent Claims (4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 38, 39)
- - 4. The neutron/proton source of claim 3 further comprising means for controlling the gas pressure in said vacuum chamber.
  - 5. The neutron/proton source of claim 4, wherein said means for controlling the gas pressure in said vacuum chamber comprises a gas feed inlet with a suitable pressure control valve and a turbo vacuum pump removably connected to said vacuum chamber.
  - 6. The neutron/proton source of claim 3, wherein said vacuum chamber is made of an electrically non-conductive material.
  - 7. The neutron/proton source of claim 3, wherein said means for applying an electric potential comprises a positively biased, high voltage power supply.
  - 8. The neutron/proton source of claim 7, further comprising feedthroughs that attach said first and second anodes to said positively-biased, high voltage power supply.
  - 9. The neutron/proton source of claim 7, wherein said positively-biased, high voltage power supply can provide a steady-state current and a pulsed current.
  - 10. The neutron/proton source of claim 7, wherein said positively-biased, high voltage power supply provides a repetitive pulse current at a preset repetition rate.
  - 11. The neutron/proton source of claim 3, wherein said means for applying an electric potential applies a positive potential between 10 kV and 200 kV.
  - 12. The neutron/proton source of claim 3, wherein said nuclear fusible gas is selected from the group of gases consisting of deuterium, a mixture of deuterium and tritium, and a mixture of deuterium and Helium-3.
  - 13. The neutron/proton source of claim 3, further comprising a means for generating a magnetic field in the axial direction attached to the circumference of said vacuum chamber.
  - 14. The neutron/proton source of claim 13, wherein said means for generating a surface magnetic field is a plurality of magnetic rings.
  - 15. The neutron/proton source of claim 13, wherein said magnetic field enhances electrostatic confinement to decrease ion/electron radial diffusion losses.
  - 16. The neutron/proton source of claim 13, wherein said magnetic field enhances electrostatic focusing to increase the fusion reaction rate density in the fusionfusuin reaction zone within the hollow cathode.
  - 17. The neutron/proton source of claim 14, wherein said means for generating a surface magnetic field is a plurality of permanent magnets.
  - 18. The neutron/proton source of claim 14, wherein said means for generating a magnetic field is an electromagnet.
  - 19. The neutron/proton source of claim 14, wherein said means for generating a magnetic field is a plurality of superconducting magnetic coils.
  - 20. The neutron/proton source of claim 13, wherein said magnetic field is effectively a surface magnetic field lying next to said inner wall of said vacuum chamber.
  - 21. The neutron/proton source of claim 20, wherein said surface magnetic field has a large magnetic field gradient extending into said vacuum chamber.
  - 22. The neutron/proton source of claim 13, wherein said magnetic field is a homogeneous magnetic field spread uniformly throughout said vacuum chamber.
  - 23. The neutron/proton source of claim 22, wherein said homogeneous magnetic field has a radial magnetic field gradient of about 10%.
  - 38. The neutron/proton source of claim 5 wherein said means for controlling the gas pressure in said vacuum chamber comprises a gas getter system whereby said gas pressure in said vacuum chamber can be maintained for extended periods with said pressure control valve closed.
  - 39. The neutron/proton source of claim 5 wherein said means for controlling the gas pressure in said vacuum chamber comprises a gas-tight reservoir whereby said hydrogen isotope gas partial pressure in said vacuum chamber can be maintained and unwanted gas species may be permanently sorbed into the reservoir material for extended periods with said vacuum chamber sealed for operation without the support of mechanical pumpspressure control valve closed.

24. An electrostatic accelerated-recirculating-ion fusion neutron/proton source, comprising:
- an axially elongated cylindrical, non-electrically conductive vacuum chamber;
  
  [first and second concave reflecting dishes, said first and second reflecting dishes disposed at and adjacent to opposite ends of said vacuum chamber so that their concave surfaces face the center of said vacuum chamber and their centers lie on the axis of said vacuum chamber;
  
  ]a cylindrical, solid, hollow cathode disposed within said vacuum chamber between said first and second reflecting dishes, wherein said cathode is 100% transparent to oscillating ions and electrons, defines a central volume and has the same axis as said vacuum chamber;
  
  first and second cylindrical, hollow anodes that are 100% transparent to oscillating ions and electrons, wherein said first anode is disposed within said vacuum chamber between said first reflecting dish and said cathode, said second anode is disposed within said vacuum chamber between said second reflecting dish and said cathode, and said first and second anodes have axes coincident with the axis of said vacuum chamber;
  
  first and second concave reflecting dishes for electrostatically reflecting and refocusing electrons in a volume along the axis inside said anodes, said first and second reflecting dishes disposed at and adjacent to opposite ends of said vacuum chamber so that their concave surfaces face the center of said vacuum chamber and their centers lie on the axis of said vacuum chamber;
  
  a nuclear fusible gas in said vacuum chamber wherein fusion reactions caused by collisions of ions produce neutrons and/or protons;
  
  a turbo vacuum pump removably connected to the vacuum chamber;
  
  a positively-biased, high voltage power supply;
  
  feedthroughs attaching said anodes to said positively-biased, high-voltage power supply; and
  
  wherein said cathode and anodes electrostatically focus said ions and electrons in regions along the axes of the cathode and anodes, respectively, wherein said ions and electrons oscillate back and forth along the axial direction of said vacuum chamber within the volume defined by the inside diameter of the central cathode and bounded on the ends by said first and second reflectors and further wherein said oscillating ions and electrons aggregate into preferred paths in the background gas thereby reducing losses of ions and electrons due to transverse diversion of ions and electrons to the electrodes.
- View Dependent Claims (25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37)
- - 25. The neutron/proton source of claim 24, wherein said positively-biased, high voltage power supply can provide aprovidea steady-state current and/or a pulsed current.
  - 26. The neutron/proton source of claim 24, wherein said positively-biased, high voltage power supply provides a repetitive pulse current at a preset repetition rate.
  - 27. The neutron/proton source of claim 24, wherein said means for applying an electric potential applies a positive potential between 50 kV and 200 kV.
  - 28. The neutron/proton source of claim 24, wherein said nuclear fusible gas is selected from the group of gases consisting of deuterium, a mixture of deuterium and tritium, and a mixture of deuterium and Helium-3.
  - 29. The neutron/proton source of claim 24, further comprising a means for generating a magnetic field in the axial direction attached to the circumference of said vacuum chamber.
  - 30. The neutron/proton source of claim 29, wherein said means for generating a surface magnetic field is a plurality of magnetic rings.
  - 31. The neutron/proton source of claim 29, wherein said means for generating a surface magnetic field is a plurality of permanent magnets.
  - 32. The neutron/proton source of claim 29, wherein said means for generating a magnetic field is an electromagnet.
  - 33. The neutron/proton source of claim 29, wherein said means for generating a magnetic field is a plurality of superconducting magnetic coils.
  - 34. The neutron/proton source of claim 29, wherein said magnetic field is effectively a surface magnetic field lying next to said inner wall of said vacuum chamber.
  - 35. The neutron/proton source of claim 34, wherein said surface magnetic field has a large magnetic field gradient extending into said vacuum chamber.
  - 36. The neutron/proton source of claim 29, wherein said magnetic field is a homogeneous magnetic field spread uniformly throughout said vacuum chamber.
  - 37. The neutron/proton source of claim 36, wherein said homogeneous magnetic field has a radial magnetic field gradient of about 10%.

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Current Assignee
George Miley, Jalal B. Javedani, Yibin Gu
Original Assignee
George Miley, Jalal B. Javedani, Yibin Gu
Inventors
Gu, Yibin, Javedani, Jalal B., Miley, George

Application Number

US10/364,898
Publication Number

US 20030223528A1
Time in Patent Office

Days
Field of Search
US Class Current

376/113
CPC Class Codes

G21B 1/05   with magnetic or electric p...

H05H 3/06   Generating neutron beams ta...

Y02E 30/10   Nuclear fusion reactors

Electrostatic accelerated-recirculating-ion fusion neutron/proton source

First Claim

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Electrostatic accelerated-recirculating-ion fusion neutron/proton source

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