Patent Number: 
Section: claims

1. A nuclear fuel, comprising:a volume of a nuclear fuel material defined by a surface,the nuclear fuel material including a plurality of grains,some of the plurality of grains having a characteristic length along at least one dimension smaller than or equal to a selected distance, the selected distance suitable for maintaining adequate diffusion of a fission product from a grain interior to at least one grain boundary in some of the grains,the nuclear fuel material including a boundary network configured to transport the fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material. 2. The nuclear fuel of claim 1, wherein the fission product comprises:a gaseous fission product, a liquid fission product, or a solid fission product. 3. The nuclear fuel of claim 1, wherein the characteristic length along at least one dimension smaller than or equal to a selected distance of some of the plurality of grains is at least partially achieved via a material processing technique. 4. The nuclear fuel of claim 3, wherein the characteristic length along at least one dimension smaller than or equal to a selected distance of some of the plurality of grains is at least partially achieved via at least one of a cold-working process, an annealing process, a normalization process, a mechanical process, a chemical treatment process or a tempering process. 5. The nuclear fuel of claim 1, wherein the characteristic length along at least one dimension smaller than or equal to a selected distance of some of the plurality of grains is at least partially achieved via an elevated temperature environment. 6. The nuclear fuel of claim 1, wherein the characteristic length along at least one dimension smaller than or equal to a selected distance of some of the plurality of grains is at least partially achieved via irradiation. 7. The nuclear fuel of claim 1, wherein some of the plurality of grains have a selected grain texture, wherein the grain texture is controlled via a grain texture control process. 8. The nuclear fuel of claim 1, wherein the nuclear fuel material has a selected porosity, wherein the porosity is controlled via a porosity control process. 9. The nuclear fuel of claim 1, wherein the characteristic length along at least one dimension smaller than or equal to a selected distance of some of the plurality of grains is at least partially achieved prior to a fission reaction process of the nuclear fuel material. 10. The nuclear fuel of claim 1, wherein the characteristic length along at least one dimension smaller than or equal to a selected distance of some of the plurality of grains is at least partially achieved during a fission reaction process of the nuclear fuel material. 11. The nuclear fuel of claim 1, wherein the characteristic length along at least one dimension of some of the plurality of grains comprises:a characteristic length along a selected dimension of some of the plurality of grains. 12. The nuclear fuel of claim 1, wherein the characteristic length along at least one dimension of some of the plurality of grains comprises:a characteristic length of some of the plurality of grains along a selected direction. 13. The nuclear fuel of claim 1, wherein some of the plurality of grains have an average characteristic length along a selected dimension smaller than or equal to a selected distance. 14. The nuclear fuel of claim 1, wherein some of the plurality of grains have an average characteristic length along a selected direction smaller than or equal to a selected distance. 15. The nuclear fuel of claim 1, wherein at least a portion of the plurality of grains has a selected statistical distribution of characteristic lengths. 16. The nuclear fuel of claim 1, wherein at least a portion of the plurality of grains has a selected set of distributions of characteristic lengths. 17. The nuclear fuel of claim 1, wherein the selected distance is a function of an operational condition of the nuclear fuel material. 18. The nuclear fuel of claim 1, wherein the selected distance is a function of a chemical composition of the nuclear fuel material. 19. The nuclear fuel of claim 1, wherein the selected distance is a function of a fission product generation rate in the nuclear fuel material. 20. The nuclear fuel of claim 1, wherein the at least one dimension is selected to maximize heat transfer from a grain interior to a grain boundary in some of the grains. 21. The nuclear fuel of claim 20, wherein the at least one dimension is selected to be substantially parallel with a thermal gradient in a grain interior in some of the grains. 22. The nuclear fuel of claim 1, wherein the selected distance suitable for maintaining adequate diffusion of a fission product comprises:a selected distance suitable for maintaining a diffusion level necessary to maintain a fission product concentration within the volume of a nuclear fuel material at or below a selected level. 23. The nuclear fuel of claim 1, wherein the boundary network of the nuclear fuel material is at least partially achieved via a material processing technique. 24. The nuclear fuel of claim 23, wherein the boundary network of the nuclear fuel material is at least partially achieved via at least one of a cold-working process, an annealing process, a normalization process, a mechanical process, a tempering process, or a chemical treatment process. 25. The nuclear fuel of claim 1, wherein the boundary network of the nuclear fuel material is at least partially achieved via a porosity control process. 26. The nuclear fuel of claim 1, wherein the boundary network of the nuclear fuel material is at least partially achieved via a grain texture control process. 27. The nuclear fuel of claim 1, wherein the boundary network of the nuclear fuel material is at least partially achieved via an elevated temperature environment. 28. The nuclear fuel of claim 1, wherein the boundary network of the nuclear fuel material is at least partially achieved via irradiation. 29. The nuclear fuel of claim 1, wherein the boundary network of the nuclear fuel material is at least partially achieved prior to a fission reaction process of the nuclear fuel material. 30. The nuclear fuel of claim 1, wherein the boundary network of the nuclear fuel material is at least partially achieved during a fission reaction process of the nuclear fuel material. 31. The nuclear fuel of claim 1, wherein the characteristic length along at least one dimension of some of the plurality of grains and formation of the boundary network of the nuclear fuel material are at least partially achieved simultaneously in a fabrication process. 32. The nuclear fuel of claim 1, wherein the boundary network of the nuclear fuel material includes at least one transportation pathway arranged to transport the fission product from at least one grain boundary of at least one of the plurality of grains to the surface of the volume of the nuclear fuel material. 33. The nuclear fuel of claim 32, wherein the at least one transportation pathway arranged to transport the fission product from the at least one grain boundary of at least one of the plurality of grains to the surface of the volume of the nuclear fuel material is defined by a region between two or more adjacent grains. 34. The nuclear fuel of claim 32, wherein the at least one transportation pathway arranged to transport the fission product from the at least one grain boundary of at least one of the plurality of grains to the surface of the volume of the nuclear fuel material intersects with the at least one grain boundary. 35. The nuclear fuel of claim 1, wherein the boundary network of the nuclear fuel material comprises:a plurality of interconnected transportation pathways arranged to transport the fission product from at least one grain boundary of at least one of the plurality of grains to the surface of the volume of the nuclear fuel material. 36. The nuclear fuel of claim 35, wherein at least one of the plurality of interconnected transportation pathways arranged to transport the fission product from at least one grain boundary of at least one of the plurality of grains to the surface of the volume of the nuclear fuel material is defined by a grain boundary between two or more adjacent grains. 37. The nuclear fuel of claim 35, wherein at least one of the plurality of interconnected transportation pathways arranged to transport the fission product from at least one grain boundary of at least one of the plurality of grains to the surface of the volume of the nuclear fuel material is defined by one or more void regions. 38. The nuclear fuel of claim 1, wherein some of the plurality of grains comprise:a grain having an interfacial layer, wherein the interfacial layer includes a material different from the material of the grain interior. 39. The nuclear fuel of claim 1, wherein the nuclear fuel material comprises:a ceramic nuclear fuel material. 40. The nuclear fuel of claim 39, wherein the ceramic nuclear fuel material comprises at least one of an oxide nuclear fuel material, a carbide nuclear fuel material, or a nitride nuclear fuel material. 41. The nuclear fuel of claim 39, wherein the nuclear fuel material comprises:a mixed oxide nuclear fuel material. 42. The nuclear fuel of claim 1, wherein the nuclear fuel material comprises at least one of a metal nuclear fuel material, a metal alloy nuclear fuel material, or an intermetallic nuclear fuel material. 43. The nuclear fuel of claim 1, wherein the nuclear fuel material includes at least one of a uranium isotope, a plutonium isotope, or a thorium isotope. 44. The nuclear fuel of claim 1, wherein the nuclear fuel material has a density equal to or below a theoretical density. 45. The nuclear fuel of claim 1, wherein the volume of a nuclear fuel material comprises:a volume of a nuclear fuel contained in a geometry maintaining container. 46. The nuclear fuel of claim 1, wherein the volume of a nuclear fuel material comprises:a self-supporting volume of a nuclear fuel material. 47. A method for fabricating a nuclear fuel, comprising:providing a nuclear fuel material, the nuclear fuel material consolidated into a solid volume of nuclear fuel material having a surface, the consolidated nuclear fuel material including a plurality of grains; andperforming one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the selected distance is suitable for maintaining adequate diffusion of a fission product from a grain interior to at least one grain boundary in some of the grains. 48. The method of claim 47, wherein the performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the selected distance is suitable for maintaining adequate diffusion of a fission product from a grain interior to at least one grain boundary in some of the grains comprises:performing one or more material processing techniques on the consolidated volume of nuclear fuel material. 49. The method of claim 48, wherein the performing one or more material processing techniques on the consolidated volume of nuclear fuel material comprises:cold-working the consolidated volume of nuclear fuel material. 50. The method of claim 48, wherein the performing one or more material processing techniques on the consolidated volume of nuclear fuel material comprises:annealing the consolidated volume of nuclear fuel material. 51. The method of claim 48, wherein the performing one or more material processing techniques on the consolidated volume of nuclear fuel material comprises:normalizing the consolidated volume of nuclear fuel material. 52. The method of claim 48, wherein the performing one or more material processing techniques on the consolidated volume of nuclear fuel material comprises:tempering the consolidated volume of nuclear fuel material. 53. The method of claim 48, wherein the performing one or more material processing techniques on the consolidated volume of nuclear fuel material comprises:performing one or more mechanical treatment processes on the consolidated volume of nuclear fuel material. 54. The method of claim 48, wherein the performing one or more material processing techniques on the consolidated volume of nuclear fuel material comprises:chemically treating the consolidated volume of nuclear fuel material. 55. The method of claim 48, wherein the performing one or more material processing techniques on the consolidated volume of nuclear fuel material comprises:performing one or more porosity control processes on the consolidated volume of nuclear fuel material. 56. The method of claim 48, wherein the performing one or more material processing techniques on the consolidated volume of nuclear fuel material comprises:performing one or more grain texture control processes on the consolidated volume of nuclear fuel material. 57. The method of claim 47, wherein the performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the selected distance is suitable for maintaining adequate diffusion of a fission product from a grain interior to at least one grain boundary in some of the grains comprises:introducing the consolidated volume of nuclear fuel material into an elevated temperature environment. 58. The method of claim 47, wherein the performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the selected distance is suitable for maintaining adequate diffusion of a fission product from a grain interior to at least one grain boundary in some of the grains comprises:irradiating the consolidated volume of nuclear fuel material. 59. The method of claim 47, wherein the performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the selected distance is suitable for maintaining adequate diffusion of a fission product from a grain interior to at least one grain boundary in some of the grains comprises:performing a fission process utilizing the consolidated volume of nuclear fuel material. 60. The method of claim 47, wherein the performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the selected distance is suitable for maintaining adequate diffusion of a fission product from a grain interior to at least one grain boundary in some of the grains comprises:performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along a selected dimension of some of the grains smaller than or equal to a selected distance. 61. The method of claim 47, wherein the performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the selected distance is suitable for maintaining adequate diffusion of a fission product from a grain interior to at least one grain boundary in some of the grains comprises:performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along a selected direction of some of the grains smaller than or equal to a selected distance. 62. The method of claim 47, wherein the performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the selected distance is suitable for maintaining adequate diffusion of a fission product from a grain interior to at least one grain boundary in some of the grains comprises:performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain an average characteristic length along a selected dimension of some of the grains smaller than or equal to a selected distance. 63. The method of claim 47, wherein the performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the selected distance is suitable for maintaining adequate diffusion of a fission product from a grain interior to at least one grain boundary in some of the grains comprises:performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain an average characteristic length along a selected direction of some of the grains smaller than or equal to a selected distance. 64. The method of claim 47, wherein the performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the selected distance is suitable for maintaining adequate diffusion of a fission product from a grain interior to at least one grain boundary in some of the grains comprises:performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a selected statistical distribution of characteristic lengths. 65. The method of claim 47, wherein the performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the selected distance is suitable for maintaining adequate diffusion of a fission product from a grain interior to at least one grain boundary in some of the grains comprises:performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a selected set of statistical distributions of characteristic lengths. 66. The method of claim 47, wherein the performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the selected distance is suitable for maintaining adequate diffusion of a fission product from a grain interior to at least one grain boundary in some of the grains comprises:performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance, wherein the selected distance is a function of an operation condition of the nuclear fuel material. 67. The method of claim 47, wherein the performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the selected distance is suitable for maintaining adequate diffusion of a fission product from a grain interior to at least one grain boundary in some of the grains comprises:performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance, wherein the selected distance is a function of a chemical composition of the nuclear fuel material. 68. The method of claim 47, wherein the performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the selected distance is suitable for maintaining adequate diffusion of a fission product from a grain interior to at least one grain boundary in some of the grains comprises:performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance, wherein the selected distance is a function of a fission product generation rate of the nuclear fuel material. 69. The method of claim 47, wherein the performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the selected distance is suitable for maintaining adequate diffusion of a fission product from a grain interior to at least one grain boundary in some of the grains comprises:performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance, wherein the at least one dimension is selected to maximize heat transfer from a grain interior to a grain boundary in some of the grains. 70. The method of claim 47, wherein the performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the selected distance is suitable for maintaining adequate diffusion of a fission product from a grain interior to at least one grain boundary in some of the grains comprises:performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the selected distance is suitable for maintaining a diffusion level necessary to maintain a fission product concentration within the volume of a nuclear fuel material at or below a selected level. 71. The method of claim 47, wherein the performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the selected distance is suitable for maintaining adequate diffusion of a fission product from a grain interior to at least one grain boundary in some of the grains comprises:performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the selected distance is suitable for maintaining a diffusion level necessary to maintain a fission product concentration within the volume of a nuclear fuel material at or below a concentration required for nucleation of the fission product. 72. The method of claim 47, wherein the performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the selected distance is suitable for maintaining adequate diffusion of a fission product from a grain interior to at least one grain boundary in some of the grains comprises:performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network having at least one transportation pathway configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material. 73. The method of claim 72, wherein the performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network having at least one transportation pathway configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material comprises:performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network having at least one transportation pathway configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the transportation pathway is defined by a region between two or more adjacent grains. 74. The method of claim 47, wherein the performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein the selected distance is suitable for maintaining adequate diffusion of a fission product from a grain interior to at least one grain boundary in some of the grains comprises:performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network having a plurality of interconnected pathways configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material. 75. The method of claim 74, wherein the performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network having a plurality of interconnected pathways configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material comprises:performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network having a plurality of interconnected pathways configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein at least one of the plurality interconnected transportation pathways is defined by a region between two or more adjacent grains. 76. The method of claim 74, wherein the performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network having a plurality of interconnected pathways configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material comprises:performing one or more processes on the consolidated volume of nuclear fuel material in order to obtain a characteristic length along at least one dimension of some of the grains smaller than or equal to a selected distance and a boundary network having a plurality of interconnected pathways configured to transport a fission product from at least one grain boundary of some of the grains to the surface of the volume of the nuclear fuel material, wherein at least one of the plurality interconnected transportation pathways is defined by one or more void regions. 77. The method of claim 47, wherein the providing a nuclear fuel material, the nuclear fuel material consolidated into a solid volume of nuclear fuel material having a surface, the consolidated nuclear fuel material including a plurality of grains comprises:providing a nuclear fuel material, the nuclear fuel material consolidated into a solid volume of nuclear fuel material having a surface, the consolidated nuclear fuel material including a plurality of grains, wherein some of the plurality of grains have an interfacial layer including a material different from the material of a grain interior. 78. The method of claim 47, wherein the providing a nuclear fuel material, the nuclear fuel material consolidated into a solid volume of nuclear fuel material having a surface, the consolidated nuclear fuel material including a plurality of grains comprises:providing a ceramic nuclear fuel material, the ceramic nuclear fuel material consolidated into a solid volume of nuclear fuel material having a surface, the consolidated nuclear fuel material including a plurality of grains. 79. The method of claim 47, wherein the providing a nuclear fuel material, the nuclear fuel material consolidated into a solid volume of nuclear fuel material having a surface, the consolidated nuclear fuel material including a plurality of grains comprises:providing a metal nuclear fuel material, a metal alloy nuclear fuel material nuclear fuel material, or an intermetallic nuclear fuel material consolidated into a solid volume of nuclear fuel material having a surface, the consolidated nuclear fuel material including a plurality of grains. 80. The method of claim 47, wherein the providing a nuclear fuel material, the nuclear fuel material consolidated into a solid volume of nuclear fuel material having a surface, the consolidated nuclear fuel material including a plurality of grains comprises:providing a nuclear fuel material including at least one of a uranium isotope, a plutonium isotope, or a thorium isotope, the nuclear fuel material consolidated into a solid volume of nuclear fuel material having a surface, the consolidated nuclear fuel material including a plurality of grains. 81. The method of claim 47, wherein the providing a nuclear fuel material, the nuclear fuel material consolidated into a solid volume of nuclear fuel material having a surface, the consolidated nuclear fuel material including a plurality of grains comprises:providing a nuclear fuel material, the nuclear fuel material consolidated into a solid volume having a density equal to or below a theoretical density, the nuclear fuel material having a surface, the consolidated nuclear fuel material including a plurality of grains. 82. The method of claim 47, wherein the providing a nuclear fuel material, the nuclear fuel material consolidated into a solid volume of nuclear fuel material having a surface, the consolidated nuclear fuel material including a plurality of grains comprises:compacting a nuclear fuel material into a consolidated solid self-supporting volume of nuclear fuel material having a surface, the consolidated nuclear fuel material including a plurality of grains. 83. The method of claim 47, wherein the providing a nuclear fuel material, the nuclear fuel material consolidated into a solid volume of nuclear fuel material having a surface, the consolidated nuclear fuel material including a plurality of grains comprises:sintering a nuclear fuel material into a consolidated solid self-supporting volume of nuclear fuel material having a surface, the consolidated nuclear fuel material including a plurality of grains. 84. The method of claim 47, wherein the providing a nuclear fuel material, the nuclear fuel material consolidated into a solid volume of nuclear fuel material having a surface, the consolidated nuclear fuel material including a plurality of grains comprises:casting a nuclear fuel material into a consolidated solid self-supporting volume of nuclear fuel material having a surface, the consolidated nuclear fuel material including a plurality of grains. 85. The method of claim 47, wherein the providing a nuclear fuel material, the nuclear fuel material consolidated into a solid volume of nuclear fuel material having a surface, the consolidated nuclear fuel material including a plurality of grains comprises:extruding a nuclear fuel material into a consolidated solid self-supporting volume of nuclear fuel material having a surface, the consolidated nuclear fuel material including a plurality of grains.