Patent Number: 044252951
Section: claims

1. A method for generating steady-state toroidal current in a toroidal plasma comprising the steps of: preparing a toroidal plasma immersed in a toroidal magnetic field, and  injecting rf energy into said plasma such that the rf energy comprises a spectrum of waves traveling substantially in a toroidal direction either substantially parallel or substantially anti-parallel to said toroidal magnetic field, said waves having substantially no parallel momentum, where  said rf energy is phased such as to increase preferentially the cyclotron motion of electrons traveling in one of said toroidal direction said electrons satisfying the resonance condition .omega.-k.sub..parallel. v.sub..parallel. =n.phi..sub.e, where .omega. is the wave frequency, k.sub..parallel. is the wave parallel wavenumber, v.sub..parallel. is the electron parallel velocity, .omega..sub.e is the electron gyrofrequency, n is an integer, and said electrons being selected from the group consisting essentially of electrons substantially on the magnetic axis or having an energy in the range of 10 to 50 times the thermal electron energy.  means for preparing a toroidal plasma immersed in a toroidal magnetic field, and  means for injecting rf energy into said plasma such that the rf energy comprises a spectrum of waves traveling substantially in a toroidal direction either substantially parallel or substantially anti-parallel to said toroidal magnetic field, said waves having substantially no parallel momentum, where  said rf energy is phased such as to increase preferentially the cyclotron motion of electrons traveling in one of said toroidal direction said electrons satisfying the resonance condition .omega.-k.sub..parallel. v.sub..parallel. =n.OMEGA..sub.e, where .omega. is the wave frequency, k.sub..parallel. is the wave parallel wavenumber, v.sub..parallel. is the electron parallel velocity, .OMEGA..sub.e is the electron gyrofrequency, n is an integer, and said electrons being selected from the group consisting essentially of electrons substantially on the magnetic axis or having an energy in the range of 10 to 50 times the thermal electron energy. 2. Method according to claim 1 wherein said plasma is prepared in a tokamak device wherein said generated toroidal current is of long duration and of sufficient intensity so that it provides a poloidal magnetic field sufficient for steady-state confinement of said plasma. 3. Method according to claim 2 where said rf energy is carried by the extraordinary plasma waves which are launched into the high-field side of said tokamak by means of waveguides carrying waves with electric field polarized substantially perpendicular to said toroidal magnetic field, wherein said waves have frequency .omega. in the range .OMEGA..sub.2 /2&lt;.omega.&lt;.OMEGA..sub.e, where .OMEGA..sub.e is the cyclotron frequency of resonant electrons in said toroidal magnetic field at some interior location in the plasma. 4. Method according to claim 3 wherein the axes of said waveguides are titled in the vertical plane as well as in the horizontal plane, so that said rf energy is preferentially absorbed by faster electrons than would be possible without said tilt, where said faster electrons typically have energy in the range of 10 to 50 times the thermal electron energy. 5. Method according to claim 2 wherein said rf energy is carried by the ordinary plasma wave which are launched into the low-field side of the tokamak by means of waveguides carrying waves with electric field polarized substantially parallel to said toroidal magnetic field, wherein said waves have frequency .omega. greater than .OMEGA..sub.e. 6. Method according to claim 5 wherein the axes of said waveguides are titled in the vertical plane as well as in the horizontal plane, so that said rf energy is preferentially absorbed by faster electrons than would be possible without sald tilt, where said faster electrons typically have energy in the range of 10 to 50 times the thermal electron energy. 7. Method according to claim 4 wherein said rf energy is carried by the extraordinary plasma wave. 8. Method according to claim 6 wherein said rf energy is carried by the ordinary plasma wave. 9. A system for generating steady-state toroidal current in a toroidal plasma comprising: 10. System according to claim 9 wherein said plasma is prepared in a tokamak device wherein said generated toroidal current is of long duration and of sufficient intensity so that it provides a poloidal magnetic field sufficient for steady-state confinement of said plasma. 11. System according to claim 10 where said rf energy is carried by the extraordinary plasma waves which are launched into the high-field side of said tokamak by means of waveguides carrying waves with electric field polarized substantially perpendicular to said toroidal magnetic field, wherein said waves have frequency .omega. in the range .OMEGA..sub.e /2&lt;.omega.&lt;.OMEGA..sub.e, where .OMEGA..sub.e is the cyclotron frequency of resonant electrons in said toroidal magnetic field at some interior location in the plasma. 12. System according to claim 11 wherein the axes of said waveguides are tilted in the vertical plane as well as in the horizontal plane, so that said rf energy is preferentially absorbed by faster electrons than would be possible without said tilt, where said faster electrons typically have energy in the range of 10 to 50 times the thermal electron energy. 13. System according to claim 10 wherein said rf energy is carried by the ordinary plasma wave which are launched into the low-field side of the tokamak by means of waveguides carrying waves with electric field polarized substantially parallel to said toroidal magnetic field, wherein said waves have frequency .omega. greater than .OMEGA..sub.e. 14. System according to claim 13 wherein the axes of said waveguides are tilted in the vertical plane as well as in the horizontal plane, so that said rf energy is preferentially absorbed by faster electrons than would be possible without said tilt, where said faster electrons typically have energy in the range of 10 to 50 times the thermal electron energy. 15. System according to claim 12 wherein said rf energy is carried by the extraordinary plasma wave. 16. Method according to claim 14 wherein said rf energy is carried by the ordinary plasma wave.