Patent Number: 042723191
Section: claims

1. A device for relativistic electron beam heating of a high density plasma to kilovolt temperatures comprising: means for generating a relativistic electron beam having a particle voltage of at least 3 MeV, a current density of at least 1 kA/cm.sup.2, and a low relativistic electron beam temperature along the stream line of said relativistic electron beam;  means for producing a plasma having a density exceeding 10.sup.17 particles/cm.sup.3 ;  means for applying said relativistic electron beam to said plasma to maintain said relativistic electron beam temperature along the stream line of said relativistic electron beam at a level sufficiently low to produce convective wave oscillations in said plasma, said convective wave oscillations created by relative drift between electrons of said relativistic electron beam and electrons of said plasma resulting from two stream and upper hybrid instabilities produced in said plasma by said relativistic electron beam;  whereby relativistic electron beam energy is deposited in said plasma to locally heat a small volume of said plasma to kilovolt temperatures at an efficiency which is a function of the strength parameter S, where: EQU S.ident.(.gamma.-.gamma..sup.-1)(n.sub.b /2n.sub.e).sup.1/3.  means for generating a relativistic electron beam having a particle voltage exceeding 3 MeV, a current density exceeding 1 kA/cm.sup.2, and minimal scattering so as to produce a low relativistic electron beam temperature along the stream line of said relativistic electron beam;  a plasma having a density exceeding 10.sup.17 particles/cm.sup.3 ;  plasma chamber means for containing said high density plasma;  a foil forming a portion of said plasma chamber means, said foil having an effective Z sufficiently low to maintain said low relativistic electron beam temperature of said relativistic electron beam along its stream line to produce convective wave oscillations in said plasma, said convective wave oscillations created by the relative drift between electrons of said relativistic electron beam and upper-hybrid instabilities produced in said plasma upon application of said relativistic electron beam to said plasma;  whereby relativistic electron beam energy is deposited in said plasma to locally heat a small volume of said plasma to kilovolt temperatures at an efficiency which is a function of the strength parameter S, where EQU S.ident.(.gamma.-.gamma..sup.-1)(n.sub.b /2n.sub.e).sup.1/3.  means for generating a relativistic electron beam having a particle voltage exceeding 3 MeV, a current density exceeding 1 kA/cm.sup.2, and minimal scattering so as to produce a low relativistic electron beam temperature along the stream line of said relativistic electron beam;  chamber means for retaining a gas within a predetermined volume at a density of at least 10.sup.17 particles/cm.sup.3 ;  means for ionizing said gas to produce a plasma having a density of at least 10.sup.17 particles/cm.sup.3 ;  a foil forming a portion of said chamber means, said foil having an effective Z sufficiently low to maintain said low relativistic electron beam temperature along the stream line of said relativistic electron beam to enhance convective wave oscillations created by the relative drift between electrons of said relativistic electron beam and electrons of said plasma, said convective wave oscillations being generated as a result of two stream and upper-hybrid instabilities produced in said plasma upon application of said relativistic electron beam to said plasma;  whereby relativistic electron beam energy is deposited in said plasma to locally heat a small volume of said plasma to kilovolt temperatures at an efficiency which is a function of the strength parameter S, where EQU S.ident.(.gamma.-.gamma..sup.-1)(n.sub.b /2n.sub.e).sup.1/3.  generating a relativistic electron beam having a particle voltage of at least 3 MeV, a current density of at least 1 kA/cm.sup.2, and a low relativistic electron beam temperature along its stream line;  producing a plasma having a density of at least 10.sup.17 particles/cm.sup.3 ;  applying said relativistic electron beam to said plasma to produce convective wave oscillations in said plasma created by the relative drift between electrons of said relativistic electron beam and electrons of said plasma, said relative drift being generated as a result of two stream and upper-hybrid instabilities, causing relativistic electron beam energy to be deposited in said plasma to locally heat a small volume of said plasma to kilovolt temperatures at an efficiency which is a function of the strength parameter S, where: EQU S.ident.(.gamma.-.gamma..sup.-1)(n.sub.b /2n.sub.e).sup.1/3. 2. The device of claim 1 further comprising means for premodulating said relativistic electron beam at a wavelength and phase velocity slightly shorter and lower than the wavelength and phase velocity of said convective wave oscillations. 3. The device of claim 1 wherein said plasma comprises DD. 4. The device of claim 1 wherein said plasma comprises DT. 5. The device of claim 1 wherein said plasma comprises HB. 6. A device for relativistic electron beam heating of a high density plasma to kilovolt temperatures comprising: 7. The device of claim 6 further comprising means for initiating electron bunching in said relativistic electron beam at a wavelength and phase velocity slightly shorter and slightly lower than the wavelength and phase velocity of said convective wave oscillations. 8. The device of claim 6 wherein said plasma comprises DD. 9. The device of claim 6 wherein said plasma comprises DT. 10. The device of claim 6 wherein said plasma comprises HB. 11. The device of claim 7 wherein said plasma comprises DD. 12. The device of claim 7 wherein said plasma comprises DT. 13. The device of claim 7 wherein said plasma comprises HB. 14. A device for producing kilovolt plasmas comprising: 15. The device of claim 14 further comprising means for initiating electron bunching in said relativistic electron beam at a wavelength and phase velocity slightly shorter and slightly lower than the wavelength and phase velocity of said convective wave oscillations. 16. A method of heating a high density plasma to kilovolt temperatures comprising the steps of: 17. The method of claim 14 further comprising the step of initiating electron bunching in said relativistic electron beam at a wavelength and phase velocity slightly shorter and slightly lower than the wavelength and phase velocity of said convective wave oscillations.