Scintillator and radiation detector including the scintillator

What is claimed is: 1. A scintillator comprising: a plastic matrix; and a first neutron-sensing material including metal-free organic luminescent compound in which excited triplet states are promoted into excited singlet states by thermal energy and wherein the excited singlet states generates luminescence at a first wavelength when the excited singlet states decay to ground state, wherein the plastic matrix is doped with molecules of the first neutron-sensing material of the scintillator, the plastic matrix comprises a plastic transparent to light of the first wavelength, and wherein the first neutron-sensing material has an internal fluorescence efficiency that is greater than 25%. 2. The scintillator of claim 1 , wherein the first neutron-sensing material has an energy gap (ΔE ST ) between the excited triplet state (T 1 ) and the excited singlet state (S 1 ) than is no more than about 600 meV. 3. The scintillator of claim 1 , wherein the first neutron-sensing material comprises a fluorescent compound having one or more carbazole moieties that can act as a donor chromophore. 4. The scintillator of claim 1 , wherein the first neutron-sensing material comprises indolocarbazole, plenylindolocarbazole, or a heteroatom substituted carbazole, dibenzothiophene, diphenylsulfone, or phenoxazine. 5. The scintillator of claim 1 , wherein the first neutron-sensing material comprises a fluorescent compound having dicyanobenzene that can act as an acceptor chromophore, or triazine that can act as an acceptor chromophore. 6. The scintillator of claim 1 , wherein the first neutron-sensing material comprises a carbazolyl dicyanobenzene. 7. The scintillator of claim 1 , wherein the internal fluorescence efficiency of the first neutron-sensing material is greater than 30%. 8. The scintillator of claim 1 , further comprising a second neutron-sensing material for detecting thermal neutrons. 9. The scintillator of claim 1 , further comprising a second neutron-sensing material for detecting thermal neutrons, wherein the first neutron-sensing material and/or the second neutron-sensing material are suspended in a plastic matrix. 10. A neutron radiation detection apparatus comprising: a scintillator configured to produce light in response to capturing neutron and non-neutron radiation, the scintillator including: a plastic matrix; and a first neutron-sensing material including a metal-free organic luminescent compound, wherein excited triplet states are promoted into excited singlet states by thermal energy and wherein the excited singlet states generate luminescence at a first wavelength when the excited singlet states decay to ground state, wherein molecules of the first neutron-sensing material are dispersed within the plastic matrix, the plastic matrix comprises a plastic material that is transparent to light of the first wavelength, and the first neutron-sensing material has an energy gap (ΔE ST ) between the excited triplet state (T 1 ) and the excited singlet state (S 1 ) than is no more than about 600 meV; and a photosensor optically coupled to the scintillator and operative to convert photons emitted by the scintillator into an electronic signal pulse. 11. The neutron radiation detection apparatus of claim 10 , further comprising a pulse-shape discriminator to process an electronic signal pulse to identify the pulse as either a non-neutron pulse or a neutron pulse. 12. The neutron radiation detection apparatus of claim 11 , wherein the pulse-shape discriminator is configured to apply a pulse-shape discrimination algorithm, the pulse-shape discrimination algorithm being capable of identifying each pulse as either a non-neutron pulse or a neutron pulse based upon the decay time of the pulse. 13. The neutron radiation detection apparatus of claim 11 , wherein the pulse-shape discriminator is configured to analyze a pulse shape of the electronic signal pulse comprising pulse amplitude as a function of time. 14. The neutron radiation detection apparatus of claim 10 , wherein neutron radiation comprises energetic neutrons and/or heavy charged particles from neutron reactions. 15. The neutron radiation detection apparatus of claim 14 , wherein the non-neutron radiation comprises gamma radiation, and the pulse-shape discriminator is configured to analyze a pulse shape of the electronic signal pulse to discriminate between gamma interactions and neutron interactions. 16. The neutron radiation detection apparatus of claim 15 , wherein analyzing a pulse shape of the electronic signal pulse to discriminate between gamma interactions and neutron interactions comprises analyzing a pulse shape of the electronic signal pulse to discriminate between gamma interactions and neutron interactions so that the fraction of gamma ray pulses erroneously counted as a neutron pulse is no more than one per million. 17. A method of detecting neutrons, the method comprising: exposing a detection device to a source of radiation, the detection device comprising: a scintillator configured to produce light in response to capturing neutron and non-neutron radiation, the scintillator including: a first neutron-sensing material including a metal-free organic luminescent compound in which excited triplet states are promoted into excited singlet states by thermal energy, wherein the excited singlet states generate luminescence at a first wavelength when the excited singlet states decay to ground state, and wherein the energy gap (ΔE ST ) between the excited triplet state (T 1 ) and the excited singlet state (S 1 ) than is no more than about 600 me V; and a plastic matrix doped with molecules of the first neutron-sensing material, the plastic matrix comprising a plastic material that is transparent to light of the first wavelength; and a photosensor optically coupled to the scintillator and operative to convert photons emitted by the scintillator into an electronic signal pulse; receiving an electronic signal pulse from the detection device at a computational device; and determining with the computational device an amount of the neutron radiation based on the electronic signal pulse. 18. The method of claim 17 , wherein the first neutron-sensing material comprises a carbazolyl dicyanobenzene. 19. The method of claim 17 , wherein the internal fluorescence efficiency of the first neutron-sensing material is greater than 25%. 20. The method of claim 17 , wherein the scintillator further comprises a second neutron-sensing material for detecting thermal neutrons.