Neutron and gamma sensitive fiber scintillators

We claim: 1. A formation evaluation tool for detecting radiation in a borehole in a volume of an earth formation, comprising: a detector including a monolithic scintillation element comprising a coherent assemblage of heat-joined fibers, wherein the fibers are made of an optically transparent scintillation media, wherein the scintillation media comprises at least one of i) organic crystalline scintillation materials, ii) amorphous glass, and iii) nanostructured glass ceramics. 2. The tool of claim 1 wherein the fibers are at least one of i) gamma ray responsive; and ii) neutron responsive. 3. The tool of claim 1 wherein the coherent assemblage of fibers is a continuous mass. 4. The tool of claim 1 wherein the fibers are solid. 5. The tool of claim 1 wherein the coherent assemblage of fibers surrounds a further scintillation media having different scintillation characteristics than the scintillation media. 6. The tool of claim 1 wherein the assemblage of fibers further includes a plurality of heavy metal rods interspersed with and substantially parallel to the fibers. 7. The tool of claim 1 wherein the scintillation element surrounds an optical light guide comprising a second coherent assemblage of heat-fused fibers. 8. The tool of claim 1 wherein the fibers are at least 50 centimeters in length. 9. The tool of claim 1 wherein the coherent assemblage of fibers is configured to allow light to travel substantially parallel to the longitudinal axis of the fibers. 10. The tool of claim 1 wherein at least a portion of the fibers are each surrounded by cladding. 11. The tool of claim 1 wherein the coherent assemblage of fibers comprises a first layer of fibers forming a first radiation responsive component and a second layer of fibers forming an optically transparent light guide. 12. The tool of claim 11 wherein the coherent assemblage of fibers comprises a third layer of fibers, interior to the first layer and second layer, forming a second radiation responsive component; and wherein the first radiation responsive component is configured to detect neutrons from the earth formation; the second layer of fibers is made of an optically transparent neutron absorptive material; and the second radiation responsive component is configured to detect neutrons from the borehole. 13. The tool of claim 1 further comprising: a drill string; and a radiation source positioned on the drill string. 14. A method for detecting radiation in a borehole in a volume of an earth formation, comprising: using a monolithic scintillation element comprising a coherent assemblage of heat-joined fibers to generate light scintillations in response to borehole radiation, wherein the fibers are made of an optically transparent scintillation media, wherein the scintillation media comprises at least one of i) organic crystalline scintillation materials, ii) amorphous glass, and iii) nanostructured glass ceramics. 15. A formation evaluation tool for detecting radiation in a borehole in a volume of an earth formation, comprising: a detector including a monolithic scintillation element comprising a coherent assemblage of heat-joined fibers, wherein the fibers are made of an optically transparent scintillation media, wherein the coherent assemblage of fibers is asymmetric. 16. The tool of claim 15 wherein the coherent assemblage of fibers surrounds a further scintillation media having different scintillation characteristics than the scintillation media; at least one photodetector configured to produce a first output in response to first light scintillations generated by the coherent assemblage of fibers and a second output in response to second light scintillations generated by the further scintillation media; and a processor configured to determine a difference in the amount of the first light scintillations and the second light scintillations from the first output and the second output. 17. The tool of claim 16 wherein the scintillation element is azimuthally sensitive. 18. The tool of claim 16 wherein the further scintillation media comprises at least one of i) single crystal material and ii) polycrystalline material. 19. The tool of claim 16 wherein the scintillation detector is configured to detect gamma rays such that, during nominal operation, the probability of detection of gamma rays in the scintillation media is maximized subject to detection of a threshold number of gamma rays in the further scintillation media.