Patent Number: 046541845
Section: claims

1. A method of operating a toroidal magnetic confinement device for confining a plasma, said plasma having a magnetic field B associated therewith, said magnetic field having an average magnetic pressure, B.sub.av.sup.2 /2, and said plasma having a pressure p, said pressure having an average value, p.sub.av, wherein B.sub.av.sup.2 =.intg.B.sup.2 d.tau./.intg.d.tau., and p.sub.av =.intg.pd.tau./.intg.d.tau., integration being over the plasma volume, said magnetic field and pressure defining a beta, .beta., associated with said plasma wherein .beta.=2 p.sub.av /B.sub.av.sup.2, and said plasma having a first and a second region of stability and a region of instability therebetween, said method comprising the steps of: (a) modifying the shape of said plasma until said plasma has a bean-shaped poloidal cross-section, a measure of said bean-shape being hte indentation at the inner most point on the plasma at the inboard side of the poidal cross-section;  (b) maintaining said beta below the threshold for instability for operation in the first region of stability, while increasing said indentation to a critical value, said critical value being the value at which said second region of stability is accessed from said first region of stability without entering said region of instability; and  (c) increasing said beta until a desired value of beta in said second region of stability is attained while maintaining said indentation at said critical value or greater.  (d) reducing said indentation to a value less than said critical value and large enough to maintain said desired value of beta in said second region of stability.  (a) applying a magnetic field B to said device, said field having an average magnetic pressure B.sub.av.sup.2 /2, where EQU B.sub.av.sup.2 =.intg.B.sup.2 d.tau./.intg.d.tau.;  (b) forming a plasma within said device, said plasma having a bean-shaped poloidal cross-section, a measure of said bean-shape being the indentation at the innermost point on the plasma at the inboard side of the poloidal cross-section, wherein said indentation is equal to at least a critical value, said critical value being the value at which said second region of stability is accessed from said first region of stability without entering said region of instability, said plasma having a pressure p, said pressure having a average value p.sub.av, where EQU p.sub.av =.intg.pd.tau./.intg.d.tau.;  (c) increasing beta, .beta., to a desired value in said second region of stability where ##EQU7##  (d) reducing said indentation to a value less than said critical value and large enough to maintain said desired value of beta. 2. The method of claim 1 further comprising the step 3. The method of claim 1 wherein said plasma has plasma pressure profiles p(y) satisfying the relationship: p(y)=p.sub.o (1-y.sup.2).sup.2, where p.sub.o is a constant, y=.psi./.DELTA..psi. and 2.pi..DELTA..psi. is the poloidal flux in the plasma. 4. The method of claim 1 wherein said plasma has a safety factor profile q(y) satisfying the relationship: ##EQU5## where q.sub.i are constants, y=.psi./.DELTA..psi. and 2.pi..DELTA..psi. is the poloidal flux in the plasma. 5. The method of claim 1 wherein the shape of said plasma cross-section is given by EQU x(t)=x+.rho. cos .gamma., EQU z(t)=E.rho. sin .gamma. 6. The method of claim 1 wherein beta is adjusted by varying at least one of p.sub.av and B.sub.av.sup.2. 7. The method of claim 1 wherein said plasma has a plasma pressure profile p(y) and safety factor profile q(y) satisfying the relationships: ##EQU6## where p.sub.o, q.sub.i are constants, y=.psi./.DELTA..sub..psi., 2.pi..DELTA..sub..psi. is the poloidal flux in the plasma. 8. The method of claim 7 wherein said device has an aspect ratio of 4 and said critical value is about 0.304. 9. The method of claim 7 wherein said device has an aspect ratio of 7 and said critical value is about 0.33. 10. The method of claim 7 wherein said device has an aspect ratio of 10 and said critical value is about 0.35. 11. The method of claim 7 wherein said device is a tokamak. 12. A method of operating a toroidal magnetic confinement device, for confining a plasma, said plasma having a first and a second region of stability and a region of instability therebetween, said method comprising the steps of: 13. The method of claim 12 further comprising the step 14. The method of claim 13 wherein said device is a tokamak. 15. The method of claim 14 wherein said plasma has pressure profiles p(y) satisfying the relationship: EQU p(y)=p.sub.o (1-y.sup.2).sup.2, 16. The method of claim 15 wherein said plasma has a safety factor profile q(y) satisfying the relationship: ##EQU8## where q.sub.i are constant. 17. The method of claim 16 wherein the shape of said plasma cross-section is given by EQU x(t)=x+.rho. cos .gamma., EQU z(t)=E.rho. sin .gamma., 18. The method of claim 12 wherein said bean shaped cross-section is formed by energizing a pusher coil located at the inner major radius side of the plasma. 19. The method of claim 12 wherein beta is established by varying at least one of p.sub.av and B.sub.av.sup.2. 20. The method of claim 1 wherein said bean-shaped cross-section is formed by energizing a pusher coil located at the inner major radius side of the plasma. 21. The method of claim 18 wherein the pusher coil is located in the vicinity of the indentation and is energized by an external current source. 22. The method of claim 20 wherein the pusher coil is located in the vicinity of the indentation and is energized by an external current source. 23. The method of claim 21 wherein the magnitude of the current through the pusher coil varies with time. 24. The method of claim 22 wherein the magnitude of the current through the pusher coil varies with time.