Patent Number: 
Section: claims

1. An electro magnetic oscillator tube with enhanced isotopes, the system comprising:at least one layer, wherein each layer of said at least one layer comprises an axial sequence of a first magnet, a conduction block, and a second magnet of opposite polarity;an elongate axially disposed emitter of isotopic particles;said conduction block having an RF port;said conduction block having an opposite electrical polarity relative to said emitter of isotopic particles forming between said emitter of isotopic particles and said conduction block;a coating of material, chosen from the group consisting of a carbon coating and a metallic coating, on an inner periphery of said conduction block representing an outermost radius of an outermost space;thermal conduction paths within radii of said conduction block between said resonant cavities;a potential defining a radial electrical vector E;said conduction block disposed in a plane about said emitter of isotopic particles and having an interior radial periphery relative to said emitter of isotopic particles defining an interaction space;an outer periphery of said interaction space defining a polar array of resonant cavities in said conduction block separated from each other by surfaces in communication with said interaction space;each of said resonant cavities having an LC value, wherein each resonant cavity generates a resonant frequency responsive to a particular annular motion and energy of isotopic particles of a cloud of isotopic particles also passing said surfaces and a plurality of entrances of said resonant cavities;said first magnet comprises an upper magnet outside and above said resonant cavity and said second magnet comprises a lower magnet of opposite polarity outside and below said resonant cavity, wherein said upper magnet and said lower magnet are in magnetic communication with said interaction space;a plurality of electrically biased grids disposed concentrically about said emitter of isotopic particles within said interaction space to influence emission characteristic of isotopic particles, within an energy spectrum of said isotopic particles to an integrity of said cloud of isotopic particles in said interaction space, shape thereof, and density of effective LC values at said resonant cavities;a connection between selected groups of said resonant cavities at locations of like electrical polarity, wherein said connection comprises conductive strapping elements within said conduction block; andeach grid in said plurality of electrically biased grids employs a polar slit. 2. The system as recited in claim 1, further comprising:a plurality of dielectric materials disposed concentrically about said emitter of isotopic particles within said interaction space to influence an emission characteristic of the isotopic particles. 3. The system as recited in claim 1, further comprising:a plurality of layers, wherein each layer of said plurality of layers is axially disposed upon each other;each layer of said plurality of layers comprises said sequence of said first magnet, said conduction block, and said second magnet of opposite polarity separated from an abutting layer by a dielectric material; andsaid emitter of isotopic particles is common to each layer of said plurality of layers. 4. The system as recited in claim 3, further comprising:within said interaction space, a plurality of dielectric layers disposed about said emitter of isotopic particles have a electrostatic grid defining a segment;each of said dielectric layers in a plane are substantially transverse to that of an axis of said emitter of isotopic particles in which a plurality of variables are radial at each of said dielectric layers and axial height of each of said electrostatic grids;each of said dielectric layers in a plane are substantially transverse to that of an axis of said emitter of isotopic particles in which an extent of transverse by each of said electrostatic grids defines a radial region through which emitted isotopics escape from said emitter of isotopic particles into said interaction space;an extent of each of said dielectric layers exists outside each of said electrostatic grids between said emitter of isotopic particles and a portion of the conduction block in a plane of each of said dielectric layers; anda radius of each of said dielectric layers within said interaction space are of a lesser dimension than that of an inner radius of said conduction block. 5. The system as recited in claim 1, in which at least one of said resonant cavities includes a dielectric material. 6. The system as recited in claim 5, in which properties of said dielectric material is tunable by adjusting an LC value of each resonant cavity. 7. The system as recited in claim 1, further comprising a power port including a rectifier for providing power conversion of said resonant energy, collected from said resonant cavities, to an electrical output of the system. 8. The system as recited in claim 1, in which said conduction block surfaces comprise:fin-like structures which define said resonant cavities of said conduction block, in which a polarity of each successive fin alternates between positive and negative during rotation of said cloud of isotopic particles. 9. The system as recited in claim 8, in which said fin-like structures are printable upon a flexible substrate which may be bent into a circular geometry having an internal radius corresponding to a desired radius of said interaction space of said conduction block. 10. The system as recited in claim 1, in which said conduction block surfaces comprise:stub-like structures which define said resonant cavities of said conduction block, in which a polarity of each successive stub alternates between positive and negative during rotation of said cloud of isotopic particles. 11. The system as recited in claim 1, in which said coating of carbon comprises a diamond coating. 12. The system as recited in claim 1, further comprising:an external heat sink in communication with thermal outputs of said radial conduction paths. 13. The system as recited in claim 1 in which said plurality of electrically biased grids are supported by at least one of said dielectric surfaces. 14. The system as recited in claim 13, further comprising:a dielectric layer separating said upper magnet and said lower magnet, each dielectric layer disposed radially outwardly of said interaction space. 15. The system as recited in claim 1, in which said plurality of electrically biased grids support at least one dielectric surface. 16. The system as recited in claim 15, in which said plurality of electrically biased grids expand axially upward and downward from at least one radial dielectric base. 17. The system as recited to claim 1, in which each grid in said plurality of electrically biased grids expand axially upwardly and downwardly from a plurality of rigid dielectric bases respectively abutting at least one of said upper magnets and said lower magnets. 18. The system as recited in claim 17, further comprising:a dielectric material disposed concentrically about said emitter of isotopic particles within said interaction space to further an emission characteristic of emitted isotopic particles. 19. The system as recited in claim 18, in which said emitter comprises a beta isotope. 20. The system as recited in claim 18, in which said emitter of isotopic particles comprises an alpha isotope. 21. The system as recited in claim 18, comprising:a non-ionizing fluid provided within said interaction space. 22. The system as recited in claim 21, comprising:said non-ionizing fluid provided radially inwardly of said plurality of electrically biased grids. 23. The system as recited in claim 21, comprising:said non-ionizing fluid provided radially outwardly of said plurality of electrically biased grids. 24. An electro magnetic oscillator tube with enhanced isotopes, the system comprising:at least one layer, wherein each layer of said at least one layer comprises an axial sequence of a first magnet, a conduction block, and a second magnet of opposite polarity;an elongate axially disposed emitter of isotopic particles;said conduction block having an RF port;said conduction block having an opposite electrical polarity relative to said emitter of isotopic particles forming between said emitter of isotopic particles and said conduction block;a coating of material, chosen from the group consisting of a carbon coating and a metallic coating, on an inner periphery of said conduction block representing an outermost radius of an outermost space;thermal conduction paths within radii of said conduction block between said resonant cavities;a potential defining a radial electrical vector E;said conduction block disposed in a plane about said emitter of isotopic particles and having an interior radial periphery relative to said emitter of isotopic particles defining an interaction space;an outer periphery of said interaction space defining a polar array of resonant cavities in said conduction block separated from each other by surfaces in communication with said interaction space;each of said resonant cavities having an LC value, wherein each resonant cavity generates a resonant frequency responsive to a particular annular motion and energy of isotopic particles of a cloud of isotopic particles also passing said surfaces and a plurality of entrances of said resonant cavities;said first magnet comprises an upper magnet outside and above said resonant cavity and said second magnet comprises a lower magnet of opposite polarity outside and below said resonant cavity, wherein said upper magnet and said lower magnet are in magnetic communication with said interaction space;a plurality of electrically biased grids disposed concentrically about said emitter of isotopic particles within said interaction space to influence emission characteristic of isotopic particles, within an energy spectrum of said isotopic particles to an integrity of said cloud of isotopic particles in said interaction space, shape thereof, and density of effective LC values at said resonant cavities;a connection between selected groups of said resonant cavities at locations of like electrical polarity, wherein said connection comprises conductive strapping elements within said conduction block; andeach grid in said plurality of electrically biased grids employs a horizontal slit.