Patent Number: 
Section: claims

1. A traveling wave nuclear fission reactor, comprising:a nuclear reactor core;at least one nuclear fission reactor fuel assembly disposed in said reactor core, said nuclear fission reactor fuel assembly being configured to generate a burnfront emitting a neutron flux, having a burning parameter, and achieving a burnup value at or below a predetermined burnup value;a neutron flux monitoring system;one or more neutron absorber control rods disposable in the nuclear fission reactor fuel assembly;a controller configured to implement a control function responsive to the neutron flux monitoring system to selectively control an amount of the one or more neutron absorber control rods at a location relative to the burnfront for achieving the burnup value at or below the predetermined burnup value, including increasing an amount of the one or more neutron absorber control rods at a rear location behind the burnfront such that a burnup value at the burnfront increases and a burnup value behind the burnfront decreases; and a drive motor configured to dispose the one or more neutron absorber control rods in response to the controller implementing the control function. 2. The traveling wave nuclear fission reactor of claim 1, wherein the controller is configured to implement the control function responsive to the neutron flux monitoring system to selectively control the amount of the one or more neutron absorber control rods at the rear location behind the burnfront for achieving the burnup value at or below the predetermined burnup value. 3. The traveling wave nuclear fission reactor of claim 1, wherein said controller is capable controlling an amount of the one or more neutron absorber control rods for achieving neutron absorption at a plurality of locations relative to the burnfront and wherein a majority of the neutron absorption due to the one or more neutron absorber control rods being at a plurality of rear locations behind the burnfront. 4. The traveling wave nuclear fission reactor of claim 1, wherein said nuclear fission reactor fuel assembly is capable of controlling an amount of a neutron reflector at a location behind the burnfront for achieving the burnup value at or below the predetermined burnup value. 5. The traveling wave nuclear fission reactor of claim 4, wherein said nuclear fission reactor fuel assembly is capable of controlling the amount of a neutron reflector for achieving neutron reflection at a plurality of locations relative to the burnfront and wherein a majority of the neutron reflection due to the neutron reflector is at a plurality of locations behind the burnfront. 6. The traveling wave nuclear fission reactor of claim 1, further comprising a neutron emitter capable of being moved from a first location behind the burnfront to a second location behind the burnfront for achieving the burnup value at or below the predetermined burnup value. 7. The traveling wave nuclear fission reactor of claim 1, further comprising a neutron emitter capable of being moved from a first location behind the burnfront to a second location proximate to the burnfront for achieving the burnup value at or below the predetermined burnup value. 8. The traveling wave nuclear fission reactor of claim 1, further comprising a neutron emitter capable of being moved from a first location behind the burnfront to a second location in front of the burnfront for achieving the burnup value at or below the predetermined burnup value. 9. The traveling wave nuclear fission reactor of claim 1, wherein said nuclear fission reactor fuel assembly is capable of controlling radiation damage to one or more of a plurality of structural materials in response to controlling the burnup value in the traveling wave nuclear fission reactor. 10. The traveling wave nuclear fission reactor of claim 9, wherein said nuclear fission reactor fuel assembly is capable of controlling the radiation damage by achieving the radiation damage value at or below a predetermined radiation damage value. 11. The traveling wave nuclear fission reactor of claim 10, further comprising a neutron emitter capable of being moved from a first location behind the burnfront to a second location behind the burnfront for achieving the radiation damage value at or below the predetermined radiation damage value. 12. The traveling wave nuclear fission reactor of claim 10, further comprising a neutron emitter capable of being moved from a first location behind the burnfront to a second location proximate to the burnfront for achieving the radiation damage value at or below the predetermined radiation damage value. 13. The traveling wave nuclear fission reactor of claim 10, further comprising a neutron emitter capable of being moved from a first location behind the burnfront to a second location in front of the burnfront for achieving the radiation damage value at or below the predetermined radiation damage value. 14. The traveling wave nuclear fission reactor of claim 1, wherein said controller is configured to implement the control function responsive to the neutron flux monitoring system to selectively control the amount of the one or more neutron absorber control rods at the rear location behind the burnfront for achieving a radiation damage value at or below a predetermined radiation damage value. 15. The traveling wave nuclear fission reactor of claim 14, wherein said controller is configured to implement the control function responsive to the neutron flux monitoring system to selectively control the amount of the one or more neutron absorber control rods for achieving neutron absorption at a plurality of locations relative to the burnfront for obtaining the radiation damage value at or below a predetermined radiation damage value and wherein a majority of the neutron absorption due to the one or more neutron absorber control rods is at a plurality of locations behind the burnfront. 16. The traveling wave nuclear fission reactor of claim 1, wherein said nuclear fission reactor fuel assembly is capable of controlling an amount of a neutron reflector at a location behind the burnfront for achieving a radiation damage value at or below a predetermined radiation damage value. 17. The traveling wave nuclear fission reactor of claim 16, wherein said nuclear fission reactor fuel assembly is capable of controlling the amount of the neutron reflector for achieving neutron reflection at a plurality of locations relative to the burnfront for obtaining the radiation damage value at or below a predetermined radiation damage value and wherein a majority of the neutron reflection due to the neutron reflector is at a plurality of locations behind the burnfront. 18. The traveling wave nuclear fission reactor of claim 1, wherein said controller is configured to implement the control function responsive to the neutron flux monitoring system to selectively modulate the neutron flux at a first location relative to the burnfront for modulating the neutron flux emitted by the traveling wave nuclear fission reactor. 19. The traveling wave nuclear fission reactor of claim 1, wherein said controller is configured to implement the control function responsive to the neutron flux monitoring system to selectively modulate the neutron flux at the rear location behind the burnfront for modulating the neutron flux emitted by the traveling wave nuclear fission reactor. 20. The traveling wave nuclear fission reactor of claim 1, wherein said controller is configured to implement the control function responsive to the neutron flux monitoring system to selectively modulate the neutron flux at a plurality of locations relative to the burnfront and wherein an amount of modulation at the plurality of locations relative to the burnfront is governed by a spatial profile. 21. The traveling wave nuclear fission reactor of claim 20, wherein the spatial profile is symmetric with respect to the burnfront. 22. The traveling wave nuclear fission reactor of claim 20, wherein the spatial profile is asymmetric with respect to the burnfront. 23. The traveling wave nuclear fission reactor of claim 20, wherein the spatial profile indicates an amount of neutron absorber control rod insertion versus distance from a central location of the nuclear reactor core, the spatial profile has a slope having a steepest portion and wherein the steepest portion of the slope of the spatial profile occurs at a first location behind the burnfront. 24. The traveling wave nuclear fission reactor of claim 19, wherein the controller is configured to implement the control function responsive to the neutron flux monitoring system to selectively modulate the neutron flux at the location relative to the burnfront, so that a majority of the modulation of neutron flux occurs at a plurality of locations behind the burnfront. 25. The traveling wave nuclear fission reactor of claim 1, wherein the nuclear fission reactor fuel assembly is capable of selectively absorbing a portion of the neutron flux at the rear location relative to the burnfront. 26. The traveling wave nuclear fission reactor of claim 1, wherein the one or more neutron absorber control rods comprise a material chosen from lithium, silver, indium, cadmium, boron, cobalt, hafnium, dysprosium, gadolinium, samarium, erbium, europium and mixtures thereof. 27. The traveling wave nuclear fission reactor of claim 1, wherein the one or more neutron absorber control rods comprise a compound chosen from silver-indium-cadmium alloy, boron carbide, zirconium diboride, titanium diboride, hafnium diboride, gadolinium titanate, dysprosium titanate and mixtures thereof. 28. The traveling wave nuclear fission reactor of claim 1, wherein said controller is configured to implement the control function responsive to the neutron flux monitoring system to control an amount of a neutron interactive material at a location relative to the burnfront for selectively modulating the neutron flux emitted by the nuclear fission reactor fuel assembly. 29. The traveling wave nuclear fission reactor of claim 28, wherein the controller is configured to implement the control function responsive to the neutron flux monitoring system to control an amount of a neutron emitter at the location relative to the burnfront for controlling the amount of the neutron interactive material at the location relative to the burnfront. 30. The traveling wave nuclear fission reactor of claim 29, wherein the neutron emitter includes a fertile isotope. 31. The traveling wave nuclear fission reactor of claim 29, wherein the neutron emitter includes an element capable of undergoing beta decay to become a fissile isotope. 32. The traveling wave nuclear fission reactor of claim 28, wherein said nuclear fission reactor fuel assembly is capable of controlling an amount of a neutron reflector at the location relative to the burnfront for controlling the amount of the neutron interactive material at the location relative to the burnfront. 33. The travelling wave nuclear fission reactor of claim 1, wherein the control function includes decreasing an amount of the one or more neutron absorber control rods at a forward location in front of the burnfront such that the burnup value at the burnfront increases and the burnup value behind the burnfront decreases. 34. The travelling wave nuclear fission reactor of claim 1, wherein the controller is configured to implement a second control function responsive to the neutron flux monitoring system to selectively control an amount of the one or more neutron absorber control rods at a location relative to the burnfront, including decreasing an amount of the one or more neutron absorber control rods at the rear location behind the burnfront. 35. The travelling wave nuclear fission reactor of claim 34, wherein the second control function responsive to the neutron flux monitoring system further includes increasing an amount of the one or more neutron absorber control rods at a forward location in front of the burnfront such that a direction of movement of the burnfront reverses or speed of movement of the burnfront decreases. 36. The travelling wave nuclear fission reactor of claim 1, wherein increasing an amount of the one or more neutron absorber control rods at the rear location includes determining an amount of neutron absorber control rod insertion as a function of distance from a nuclear fission igniter of the travelling nuclear fission reactor.