Patent Number: 
Section: claims

1. A particle accelerator system, comprising:a source assembly for emitting a stream of isotopic slugs, each slug comprising a train of microbunches;at least one RF (radiofrequency) accelerator section for receiving said slug stream and focusing, accelerating and funneling said slug stream until a plurality of high-current, parallel slug trains emerges;a telescoper for receiving said plurality of high-current parallel slug trains and emitting different isotopic species into a single common-rigidity beamline, wherein that said species arrive at at least one a fusion target in a specified sequence;at least one snugger for receiving said common-rigidity beamline and snugging slugs within said common-rigidity beamline until they drift to points at prescribed distances from said least one target in at least one reaction chamber. 2. The system of claim 1, wherein said source assembly comprises:a patterned array of heavy ion sources, each source emitting pulses of a separate isotopic species in a sequence determined by a control element; anda HVDC (high-voltage direct current) preaccelerator for accelerating said heavy ion pulses to a synchronous speed required by said at least one RF accelerator section, wherein electrodes in said HVDC preaccelerator are disposed in a manner that mirrors patterning of said array of heavy ion sources. 3. The system of claim 1, wherein said at least one RF accelerator section comprises:a first RF section comprising a multi-channel radiofrequency quadrupole (RFQ), which provides strong focusing fields and a smoothly increasing accelerating field to approach isentropic conversion of a DC incoming slug beam into microbunches in a continuous stream at an RF frequency;an aligner for funneling slugs of a variety of isotopes from said first RF section structure section to a single collinear beam comprising a variety of isotopic slugs specified by a programmed time sequence and for increasing an average current of a slug; anda plurality of additional RF sections wherein two incoming beams are zipped into a single beam to approximately double the average current of each slug as it passes between a first accelerator section and a following accelerator section, wherein an RF frequency of the following section is at double the frequency of the first section, conducted in a complementary arrangement of beamline magnets and a RF deflector, wherein the two zipped beams are progressively aligned into one beam on a common axis. 4. The system of claim 1, wherein said telescoper comprises an accelerator section having at least one pulse-switched magnet;wherein said system further comprises a merger for merging a multiplicity of beams in a transverse phase space as they emerge from said telescoper into a single beam;said system further comprising:a Slug-Slug Delay Line for sorting successive sections of beam, provided with time gaps between said sections by gating ion source emission or applying magnetic or electric fields at a later stage of low-energy acceleration, into parallel beamlines, in synchronism at the level of the individual microbunches in the beam sections in parallel beamlines, to maintain the microbunch structure in common RF sections with multiple bores for the parallel beams. 5. The system of claim 1, wherein said at least one snugger differentially accelerates each microbunch within a slug within a beamline to move microbunches within slugs closer together while being maintained under the control of RF phase focusing;wherein said snugger comprises a succession of blocks of RF accelerator sections, said blocks operating with a succession of RF frequencies, said succession of RF frequencies programmed to coordinate acceleration of the multiplicity of isotopic slugs, each of which has a specific characteristic speed; andwherein said snugger further comprises a snug-stopper for temporarily stopping snugging of slugs until they drift to points at prescribed distances from at least one target in at least one reaction chamber. 6. A driver comprising:a particle accelerator system comprising:a source assembly for emitting a stream of isotopic slugs, each slug comprising a train of microbunches;at least one RF (radiofrequency) accelerator section for receiving said slug stream and focusing, accelerating and funneling said slug stream until a plurality of high-current, parallel slug trains emerges;a telescoper for receiving said plurality of high-current parallel slug trains and emitting different isotopic species into a single common-rigidity beamline so that said species arrive at a target in a specified sequence;at least one snugger for receiving said common-rigidity beamline and snugging slugs within said common-rigidity beamline until they drift to points at prescribed distances from at least one target in at least one reaction chamber;a delay line for rearranging beam slugs to collect small individual spaces between slugs and sort slugs into parallel beamlines to produce a smaller momentum spread at focusing on the target;a delay line for eliminating at least a portion of a distance between centers of successive slugs;a controller for controlling arrival of said slugs at targets in specified reaction chambers according to a specified schedule;at least one slicker for imparting specified velocity differentials into microbunches of said slugs at specified distances upstream from each of said reaction chambers;a wobbler for swirling a beam spot rapidly around a target to heat an annular region of the target with smooth energy deposition density in said target; andat least one set of final focusing lenses for focusing said beam on said target. 7. The driver of claim 6, wherein said delay line for eliminating space between successive isotopic slugs comprises helical delay line (HDL), wherein a common HDL is used for all isotopes;wherein at least a portion of said distance between centers occurs as a result of a snugging process wherein total average current of each of said slugs is increased and length of each of said slugs is decreased;wherein said HDL comprises a plurality of coils, wherein a length of each coil is approximately equal to the distance between centers of successive slugs;wherein a first slug in a slug train traverses the full length of the HDL before its exit point;wherein successive slugs of progressively faster ions exit the HDL sequentially, after traversing progressively fewer turns of the HDL; andwherein exits for various slugs are approximately at a same azimuthal point on the HDL. 8. The driver of claim 6, wherein said at least one slicker comprises a slicker for each reaction chamber; andwherein said at least one slicker comprises at least one slicker for a compression pulse and at least one slicker for each fast ignition pulse;wherein slicking in separate slickers for the fast ignition and compression pulse occurs after bifurcation of a beam pulse into separate beamlines with separate slickers for the fast ignition and the compression pulses;wherein all isotopic species use one set of beamlines from the isotope-isotope delay line (HDL) to the individual slicker at each of the reaction chambers; andwherein, said slicker comprises one or more sections of a linear accelerator operating at a RF frequency in which different microbunches are differentially accelerated to cause their centers to approach each other;wherein, during slicking, individual microbunches stretch along an axis of a phase space ellipse while the area of said phase space ellipse remains approximately constant during transport in beamlines toward a target, wherein individual microbunches become longer, skinnier ellipses as they simultaneously approach said fusion target and the combined action of individual microbunches stretching, while moving closer together and ultimately into one another in physical space and over one another in the longitudinal phase space, produces a net current amplification, to shape the total beam current on the target, by controlling the slick accelerator parameters and timing. 9. The driver of claim 6, wherein said wobbler comprises an RF wobbler;wherein said wobbler is located upstream from said at least one final focusing lens;wherein a block of slugs for a compression pulse is subjected to said wobbler and wherein a block of slugs for a fast ignition pulse is not subjected to said wobbler because said block of slugs for fast ignition pulse is directed at a center of a target;wherein using slower ions for a fast ignition pulse, compared to a speed of compression pulse ions provides a space in time between the two pulses that turns the wobbler on or off;wherein a block of slugs for a compression pulse is subjected to said wobbler with the wobbler fields programmed to cause the beam wobble on the target; andwherein various slugs for a fast ignition pulse are subjected to said wobbler with the wobbler fields programmed to cause said slugs of the fast ignition pulse to be directed at the end caps of the target at radial distances from the axis programmed to heat said end caps at a radius that varies with time.