Neutron detector with interblended liquid scintillator

The invention claimed is: 1. A neutron detector cell comprising: an elongated detector tube having a first end and an opposing second end and including a peripheral wall defining an enclosed channel, a liquid scintillator disposed in the elongated channel, said liquid scintillator including an ionic liquid blended with a controlled optical attenuator and at least one of a scintillation enhancer and a moderator such that the liquid scintillator is configured to generate a light pulse at an interaction point in response to an incident neutron, and configured such that light transmitted along the elongated detector tube from said light pulse is attenuated by an amount that is inversely proportional to a distance traveled from the interaction point along the elongated detector tube; a first photo-detector optically coupled to the first end of said elongated detector tube, said first photo-detector configured to detect a first portion of said light pulse that is transmitted from said interaction point through said liquid scintillator to the first end, and to generate a first detection signal including a first light magnitude value indicating a first light amount of said first portion; and a second photo-detector optically coupled to the second end of said elongated detector tube, said second photo-detector configured to detect a second portion of said light pulse transmitted from said interaction point through said liquid scintillator to the second end, and to generate a second detection signal including a second light magnitude value indicating a second light amount of said second portion, whereby a longitudinal location of said light pulse along said elongated detector tube is determinable by a difference between said first and second light magnitude values. 2. The neutron detector cell of claim 1 , wherein the ionic liquid of the liquid scintillator comprises one or more anions derived from the group including derived from the group including [BF 4 ] − , [PF 6 ] − , [CF 3 SO 2 NSO 2 CF 3 ] − , [CF 3 SO 3 ] − , and [N(CN) 2 ] − , and one or more cations derived from the group including imidazolium, pyridinium, pyrimidinum, pyrazinium, pyrazolium, piperdinium and pyrrolidinium. 3. The neutron detector cell of claim 2 , wherein the liquid scintillator comprises said ionic liquid blended with at least one of Athracene, an organic scintillator and inorganic scintillator. 4. The neutron detector cell of claim 2 , wherein the liquid scintillator comprises said ionic liquid blended with at least one of Lithium and Boron. 5. The neutron detector cell of claim 2 , wherein the liquid scintillator comprises said ionic liquid blended with at least one organic dye. 6. The neutron detector of claim 1 , wherein the ionic liquid comprises a Room Temperature Ionic Liquid (RTIL). 7. The neutron detector cell of claim 6 , wherein the liquid scintillator consists essentially of said RTIL blended with Anthracene. 8. The neutron detector cell of claim 6 , wherein the liquid scintillator consists essentially of said RTIL blended with Lithium isotopes 6 Li, Boron isotopes 10 B and an organic dye. 9. The neutron detector cell of claim 6 , wherein the liquid scintillator consists essentially of said RTIL blended with Lithium isotopes 6 Li, Boron isotopes 10 B, an organic dye and Anthracene. 10. The neutron detector cell of claim 1 , further comprising a tapered light guide disposed between the first end of said detector tube and said first photo-detector. 11. The neutron detector cell of claim 1 , wherein the peripheral wall of the detector tube comprises one of plastic and glass, and wherein the neutron detector cell further comprises: a reflective layer comprising a reflective material disposed on an outside surface of the peripheral wall; and a light-sealing layer comprising a material that is opaque to black light disposed on an outside surface of the reflective layer. 12. A neutron detector cell comprising: an elongated detector tube having a first end and an opposing second end and including a peripheral wall defining an enclosed channel, a liquid scintillator disposed in the elongated channel, said liquid scintillator including an ionic liquid blended with at least one of a scintillation enhancer, a moderator and a controlled optical attenuator; a first photo-detector optically coupled to the first end of said detector tube, said first photo-detector configured to detect a light pulse generated by said liquid scintillator, and to generate a first detection signal including a first light magnitude value indicating a first portion of said light pulse arriving at said first end of said detector tube; and a second photo-detector optically coupled to the second end of said detector tube, said second photo-detector configured to detect said light pulse and to generate a second detection signal including a second light magnitude value indicating a second portion of said light pulse arriving at said second end of said detector tube, wherein the ionic liquid of the liquid scintillator comprises one or more anions derived from the group including derived from the group including [BF 4 ] − , [PF 6 ] − , [CF 3 SO 2 NSO 2 CF 3 ] − , [CF 3 SO 3 ] − , and [N(CN) 2 ] − , and one or more cations derived from the group including imidazolium, pyridinium, pyrimidinum, pyrazinium, pyrazolium, piperdinium and pyrrolidinium blended with at least one organic dye, and wherein the organic dye comprises an anthraquinone-based organic dye. 13. A neutron detector cell comprising: an elongated detector tube having a first end and an opposing second end and including a peripheral wall defining an enclosed channel, a liquid scintillator disposed in the elongated channel, said liquid scintillator including an ionic liquid blended with at least one of a scintillation enhancer, a moderator and a controlled optical attenuator; a first photo-detector optically coupled to the first end of said detector tube, said first photo-detector configured to detect a light pulse generated by said liquid scintillator, and to generate a first detection signal including a first light magnitude value indicating a first portion of said light pulse arriving at said first end of said detector tube; and a second photo-detector optically coupled to the second end of said detector tube, said second photo-detector configured to detect said light pulse and to generate a second detection signal including a second light magnitude value indicating a second portion of said light pulse arriving at said second end of said detector tube, wherein the ionic liquid comprises a Room Temperature Ionic Liquid (RTIL), and wherein the liquid scintillator consists essentially of said RTIL blended with Lithium isotopes 6 Li and Boron isotopes 10 B.