Negative ion-based neutral beam injector

What is claimed is: 1. A negative ion-based beam injector comprises an ion source configured to produce a negative ion beam, wherein the ion source includes a plasma box, wherein internal walls of the plasma box are maintainable at elevated temperatures of about 150-200° C., a pre-accelerator, and a high energy accelerator interconnected to and spaced apart from the pre-accelerator and ion source. 2. The injector of claim 1 , wherein the pre-accelerator is an electrostatic multi aperture grid in the ion source. 3. The injector of claim 2 , further comprising a distributing manifold for directly supplying cesium on the multi aperture grid of the pre-accelerator. 4. The injector of claim 2 , wherein the multi aperture grid is positively biased to repel back streaming positive ions. 5. The injector of claim 1 , further comprising a pair of deflecting magnets interposing the pre-accelerator and high energy accelerator, wherein the pair of deflecting magnets enables a beam from the pre-accelerator to shift off axis before entering the high energy accelerator. 6. The injector of claim 1 , wherein the pre-accelerator includes external magnets to deflect co-extracted electrons in an ion extraction and pre-acceleration regions. 7. The injector of claim 1 , further comprising a pumping system to pump gas out from a pre-acceleration gap. 8. The injector of claim 1 , wherein the high energy accelerator is spaced apart from the ion source by a transition zone comprising a low energy beam transport line. 9. The injector of claim 8 , wherein the low energy beam transport line includes cesium traps. 10. The injector of claim 9 , wherein the low energy beam transport line includes bending magnets that deflect and focus the beam onto the axis of the high energy accelerator. 11. The injector of claim 1 , further comprising a neutralizer interconnected to the high energy accelerator. 12. A negative ion-based beam injector comprises an ion source adapted to produce a negative ion beam, a pre-accelerator coupled to the ion source, a high energy accelerator, and a pair of deflecting magnets, interposing the pre-accelerator and high energy accelerator, wherein the pair of deflecting magnets enables a beam from the pre-accelerator to shift off axis before entering the high energy accelerator. 13. The injector of claim 12 , further comprising a plurality of magnets externally coupled to the pre-accelerator to deflect co-extracted electrons in an ion extraction and pre-acceleration regions. 14. The injector of claim 12 , wherein the ion source includes a plasma box having internal walls maintainable at elevated temperatures of about 150-200° C. 15. The injector of claim 12 , wherein the pre-accelerator comprises an electrostatic multi aperture grid. 16. The injector of claim 15 , the further comprising a distributing manifold for directly supplying cesium on the electrostatic multi aperture grid. 17. The injector of claim 12 , wherein the pre-accelerator comprises external magnets to deflect co-extracted electrons in an ion extraction and pre-acceleration regions. 18. The injector of claim 12 , further comprising cesium traps interposing the pre-accelerator and the high energy accelerator. 19. The injector of claim 12 , further comprising a residual ion energy recuperator. 20. The injector of claim 12 , further comprising a neutralizer coupled to the high energy accelerator. 21. The injector of claim 20 , wherein the neutralizer includes a plasma neutralizer comprising a multi-cusp plasma confinement system with high field permanent magnets. 22. The injector of claim 20 , wherein the neutralizer includes a photon neutralizer comprising a cylindrical cavity with reflective walls.