Patent Number: 044977689
Section: claims

1. A method for quantitatively evaluating total fissile and total fertile nuclide content in samples, which comprises the steps of: a. generating repetitively pulsed gamma radiation;  b. directing said gamma radiation onto a partially transparent target which generates photoneutrons while allowing a substantial portion of said gamma radiation to pass through;  c. thermalizing said photoneutrons such that their reaction probability with fissile isotopes is substantially enhanced;  d. causing said gamma radiation and said thermalized photoneutrons to impinge upon a sample;  e. measuring the flux of said thermalized photoneutrons in the vicinity of the sample during time intervals in between the termination of a particular gamma radiation pulse and the commencement of the following one;  f. measuring the intensity of said gamma radiation in the vicinity of the sample;  g. measuring prompt and delayed fast neutron emission from the sample resulting from photofission of fertile and fissile nuclides interacting with said impinging gamma radiation, and from fission of fissile nuclides capturing said thermalized photoneutrons during said time intervals;  h. accumulating a plurality of said prompt and delayed fast neutron emission measurements, and a plurality of said thermalized neutron flux measurements until statistically significant measurements are obtained; and  i. relating said accumulated emitted prompt and delayed fast neutron measurements normalized by said accumulated thermalized neutron flux measurements and said intensity of said gamma radiation to known gamma and neutron cross sections for the fissile and fertile nuclides contained in the sample to obtain the quantitative assay.  a. means for generating repetitively pulsed gamma radiation;  b. means for filtering said gamma radiation to remove photons of energy lower than about 2 MeV;  c. means for generating photoneutrons from a portion of said filtered gamma radiation, the remainder of said filtered gamma radiation impinging on a sample;  d. means for thermalizing said photoneutrons, whereby said photoneutrons impinge upon the sample;  e. means for measuring said thermalized photoneutron flux in the vicinity of the sample during time intervals in between the termination of a particular gamma radiation pulse and the commencement of the following one;  f. means for measuring the intensity of said gamma radiation in the vicinity of the sample;  g. means for measuring prompt and delayed fast neutron emission from the sample resulting from the photofission of fertile and fissile nuclides interacting with a substantial portion of said remainder of said filtered gamma radiation, and from fission of fissile nuclides capturing said thermalized photoneutrons during said time intervals; and  h. means for accumulating a plurality of said prompt and delayed fast neutron emission measurements, and a plurality of said thermalized neutron flux measurements until statistically significant measurements are obtained, whereby said accumulated emitted prompt and delayed fast neutron measurements normalized by said accumulated thermalized neutron flux measurements and said intensity of said gamma radiation can be related to known gamma radiation and neutron cross sections for the fissile and fertile nuclides contained in the sample to obtain the quantitative assay.  a. an electron accelerator capable of providing greater than about 1 ma of electron beam current in short duration pulses at a repetition rate between 1 and 60 Hz, and at energies in excess of about 10 MeV; and  b. a target attached to the output of said linear accelerator which generates bremsstrahlung radiation when bombarded with said short pulses of electrons, said bremsstrahlung radiation thereby containing photons with energy in excess of about 10 MeV. 2. The method as described in claim 1, wherein said pulsed gamma radiation has photon energy in excess of about 10 MeV. 3. The method as described in claim 2, wherein said pulsed gamma radiation is filtered to remove photons of lower energy than about 2 MeV before impinging on the sample. 4. The method as described in claim 3, wherein said photoneutron thermalization step is caused to be substantially completed within about 0.5 ms after said termination of a particular gamma radiation pulse. 5. The method as described in claim 4, wherein said prompt fast neutron measurement step is performed between about 0.5 and 2.5 ms after said termination of a particular gamma radiation pulse in order to determine the number of thermal-neutron-induced fissions which are measurable during this time period, and wherein said delayed fast neutron measurement step is performed between about 5.5 ms after said termination of a particular gamma radiation pulse and said commencement of the following gamma radiation pulse in order to determine the number of photofissions from both fertile and fissile nuclides present in the sample which process is measurable during this later time period. 6. The method as described in claim 5, wherein said gamma radiation generated neutron flux is adjusted such that said emitted delayed fast neutron flux is comprised principally of neutrons from said photofission of fertile nuclides while allowing sufficient prompt fast neutron emission from said thermal neutron fission process in the fissile nuclides to enable said statistically significant neutron measurements to be obtained in a practical accumulation time period. 7. The method as described in claim 6, wherein said pulsed gamma radiation is derived from an electron accelerator having a beam current greater than approximately 1 ma, a pulse duration less than about 4 .mu.s, and a pulse repetition rate within the range of substantially 1-60 Hz, the electrons generated therefrom producing said gamma radiation by a bremsstrahlung process upon striking a heavy metal target. 8. An apparatus for quantitatively evaluating total fissile and total fertile nuclide content in samples, which comprises in combination: 9. The apparatus as described in claim 8, wherein said photoneutron thermalization means includes the walls of a chamber, said chamber surrounding the sample. 10. The apparatus as described in claim 9, wherein said thermalized photoneutron flux measuring means includes at least one bare low pressure .sup.3 He proportional counter located inside said chamber in the vicinity of the sample. 11. The apparatus as described in claim 10, wherein said prompt and delayed fast neutron emission measurement means includes at least one high pressure .sup.3 He proportional counter surrounded by polyethylene which is in turn surrounded by cadmium foil, in order to block said thermalized photoneutrons, and located within said chamber in the vicinity of the sample. 12. The apparatus as described in claim 11, wherein said pulsed gamma radiation means further comprises: 13. The apparatus as described in claim 12, wherein said filtering means includes a polyethylene slab placed between said target and said chamber. 14. The apparatus as described in claim 13, wherein said chamber wall includes a thick polyethylene inner wall surrounded by a layer of cadmium foil which is further surrounded by a thick outer wall of borated polyethylene, said cadmium and borated polyethylene layers being intended to reduce the effects of stray neutrons generated by said electron accelerator away from the direction of said electron beam. 15. The apparatus as described in claim 14, wherein said target includes niobium foil. 16. The apparatus as described in claim 15, wherein said neutron generating means includes a beryllium sheet. 17. The apparatus as described in claim 16, wherein each of said bare low pressure .sup.3 He proportional counters further comprises an about 2.5 cm diameter metal tube, approximately 51 cm long containing about 1% .sup.3 He and 99% .sup.4 He at low pressure. 18. The apparatus as described in claim 17, wherein each of said high pressure .sup.3 He proportional counters further comprises an about 5 cm diameter metal tube, approximately 34 cm long containing about 3 atmospheres of .sup.3 He and surrounded by about 1.25 cm of polyethylene which is in turn surrounded by about 1.7 mm thick cadmium foil. 19. The apparatus as described in claim 18, wherein said polyethylene inner chamber wall is about 10 cm thick, said surrounding cadmium foil is approximately 0.6 mm thick, and said borated polyethylene outer chamber wall is about 10 cm thick.