Patent Number: 
Section: claims

1. A system for compressing a fuel source, the system comprising:a first component configured to segregate a first plurality of ions based upon their corresponding isotopes into a first plurality of microbunches, each microbunch comprising a grouping of said ions, each group associated with a same species;a second component configured to:separate the first plurality of microbunches in space by applying a first electromagnetic wave in a resonant radiofrequency (RF) structure at a first RF frequency; andadjust the first electromagnetic wave to reduce the distance between the microbunches of the first plurality of microbunches;a third component configured to reduce the distance between a center of mass of the first plurality of ions and a center of mass of a second plurality of ions; anda fuel chamber comprising at least one layer surrounding at least a portion of a fuel source, the at least one layer configured to receive the first plurality of ions and the second plurality of ions such that compression of the one or more layers is maximized relative to one or more Bragg peaks associated with the first plurality of ions and the second plurality of ions. 2. The system of claim 1, wherein the second plurality of ions are more widely dispersed than the first plurality of ions and wherein the system is configured to provide the second plurality of ions to a fourth component before the first plurality of ions are delivered to the second component, wherein the fourth component is configured to:separate the second plurality of microbunches in space by applying a second electromagnetic wave; andincrease the frequency of the second electromagnetic wave to reduce the distance between the microbunches of the second plurality of microbunches. 3. The system of claim 1, wherein the third component is a telescope configured to merge a plurality of ion beams. 4. The system of claim 1, wherein the first component comprises a species alignment device. 5. The system of claim 1, wherein the first, second, and third components comprise RF cavities. 6. The system of claim 1, wherein first plurality of ions is configured to drive the waists of the fuel source. 7. The system of claim 1, wherein second plurality of ions is configured to compress end caps located in the fuel chamber. 8. A system for preparing an ion composition, the system comprising:a first component configured to segregate a first plurality of ions based upon their corresponding isotopes into a first plurality of microbunches, each microbunch comprising a grouping of said ions, each group associated with a same species;a second component configured to:separate the first plurality of microbunches in space by applying a first electromagnetic wave in a resonant radiofrequency (RF) structure at a first RF frequency; andadjust the first electromagnetic wave to reduce the distance between the microbunches of the first plurality of microbunches; anda third component configured to reduce the distance between a center of mass of the first plurality of ions and a center of mass of a second plurality of ions. 9. The system of claim 8, wherein the third component is a telescope configured to merge a plurality of ion beams. 10. The system of claim 8, wherein the first component comprises a species alignment device. 11. The system of claim 8, wherein the first, second, and third components comprise RF cavities. 12. The system of claim 8, wherein first plurality of ions is configured to drive the waists of the fuel source. 13. A system for compressing and igniting fuel in a fuel capsule, the system comprising:a first component configured to produce a timed sequence of continuous blocks of ions in a plurality of parallel streams in independent channels, each of said blocks based upon a different one of a set of isotopes, said plurality of parallel channels being replicated in a plurality of parallel units of said first component, each parallel unit comprising an array of a plurality of originating ion sources, each one of the said plurality of originating ion sources in each of the said arrays being based upon a different one of the respective isotopes;a second component configured to subdivide each one of the sequences of continuous blocks of the pluralities of parallel streams of the first pluralities of ions based upon their respective isotopes in the first pluralities of parallel channels and transform the continuous blocks into regular time-sequences of first blocks of pluralities of microbunches, each of said blocks of microbunches comprising ions of only one of the respective isotopes, by applying a first electromagnetic wave in a resonant radiofrequency (RF) structure at a first RF frequency;a third component comprising a system of magnets, one or more of of which comprise pulsed magnetic fields and one or more of which comprise continuous magnetic fields, configured to route in individual channels, each one of the pluralities of parallel beams of the sequences of blocks of microbunches comprising ions of the respective isotopes originated in the ion sources of the first component, in each of the plurality of parallel units of the first component, said routing culminating in directing all of the parallel beams of each one of the plurality of parallel units, in the unchanged time-sequence of blocks of microbunches of the respective isotopes, into a single beamline, the number of said beamlines having a same plurality as that of the plurality of parallel units of the first component;a fourth component configured to step-wise compact in space and time, pairs of the beams, reducing the number of parallel beamlines from the plurality of parallel units of the first component by a defined factor, said factor being a defined power of two, by interlacing the microbunches within the pluralities of blocks of microbunches of the respective isotopes as created at a first RF frequency in the second component, into a next plurality of beams comprising the unchanged sequence of blocks of mirobunches of the respective isotopes, with each of the regularly time-spaced microbunches appropriately positioned on RF waves of a second RF accelerator structure, said second RF accelerator structure at a RF frequency that is twice that of the first RF frequency, said interlacing halving a distance between a center of mass of successive microbunches, resulting in the blocks of the second plurality of beams comprising the unchanged sequence of blocks of microbunches of the respective isotopes having twice the number of microbunches of their respective isotopes as compared to the number of microbunches comprising the blocks of the same isotopes in each of the first plurality of beamlines in the first RF accelerator structure;said fourth component comprising multiple steps of doubling a beam current by said interlacing of the microbunches of pairs of beams from an upstream accelerator structure at one RF frequency into a second, downstream RF accelerator structure operating at twice the RF frequency of the upstream RF accelerator structure, said multiple steps of interlacing microbunches at doublings of the RF frequency of the RF accelerator structures increasing the number of microbunches in the blocks of respective isotopes by a factor that is a power of two, wherein said power of two comprises a multiplicity of interleaving steps, said increase in number of microbunches per block increasing the beam currents by a same factor.