Patent Number: 
Section: claims

1. A method for absorbing neutrons, comprising:positioning a plurality of sample materials in a neutron absorber comprising:disposing each sample material of the plurality of sample materials in one jacket of a plurality of jackets;disposing each jacket in one discrete, cylindrical bore of a plurality of discrete, cylindrical bores formed in a cylindrical heat sink of the neutron absorber and extending through an entirety of the neutron absorber along a longitudinal axis of the neutron absorber; andpositioning each jacket within each discrete bore to form an annulus extending along an entire length of the sample material between the jacket and a surface of the heat sink forming the discrete bore;positioning the neutron absorber in a neutron field;exposing the neutron absorber to the neutron field;absorbing at least some of the neutrons from the neutron field with the neutron absorber;flowing a coolant through a plurality of discrete coolant channels formed in the cylindrical heat sink separate from the plurality of discrete bores and extending through an entirety of the neutron absorber along the longitudinal axis of the neutron absorber; andremoving heat from the neutron absorber with the coolant. 2. The method of claim 1, wherein exposing the neutron absorber to the neutron field comprises exposing the neutron absorber to the neutron field including fast neutrons comprising neutrons exhibiting an energy greater than about 0.1 million electron volts (MeV) and thermal neutrons comprising neutrons exhibiting an energy less than about 0.68 electron volts (eV), and further comprising producing a region adjacent the neutron absorber exhibiting a fast-to-thermal neutron ratio of at least about 15 by absorbing a portion of the thermal neutrons with at least one material forming the neutron absorber. 3. The method of claim 2, further comprising producing a region adjacent the neutron absorber exhibiting a neutron flux intensity of at least about 1×1015 n/cm2·s by absorbing a portion of the thermal neutrons with the at least one material forming the neutron absorber. 4. The method of claim 2, further comprising producing a region adjacent the neutron absorber exhibiting a fast-to-thermal neutron ratio in a range of about 15 to about 50 and a neutron flux intensity of at least about 1×1015 n/cm2·s by absorbing a portion of the thermal neutrons with the at least one material forming the neutron absorber. 5. A method for absorbing neutrons, comprising:positioning a plurality of sample materials in a neutron absorber comprising:disposing each sample material of the plurality of sample materials in a jacket;disposing the jacket in a bore formed in a heat sink of the neutron absorber; andpositioning the jacket within the bore to form an annulus extending along an entire length of the sample material between the jacket and a surface of the heat sink forming the bore;positioning the neutron absorber in a neutron field;exposing the neutron absorber to the neutron field;absorbing at least some of the neutrons from the neutron field with the neutron absorber;flowing a coolant through a portion of the neutron absorber;removing heat from the neutron absorber with the coolant; andforming the neutron absorber from a first material comprising hafnium and a second material comprising aluminum. 6. The method of claim 5, wherein forming the neutron absorber from a first material comprising hafnium and a second material comprising aluminum comprises selecting the first material to comprise a hafnium/aluminum intermetallic compound. 7. The method of claim 6, wherein selecting the first material to comprise a hafnium/aluminum intermetallic compound comprises selecting the first material to comprise Al3Hf. 8. The method of claim 5, further comprising forming the neutron absorber from a first material exhibiting a thermal neutron cross-section of at least about 50 barns, and a second material exhibiting a thermal conductivity of at least about 1 W/cm·K. 9. The method of claim 1, wherein flowing a coolant through a plurality of discrete coolant channels formed in the cylindrical heat sink comprises flowing water through the plurality of discrete coolant channels formed in the cylindrical heat sink. 10. A method for absorbing neutrons, comprising:positioning a neutron absorber having at least one sample material disposed in a plurality of bores formed therein in a neutron field;exposing the neutron absorber to the neutron field including fast neutrons comprising neutrons exhibiting an energy greater than about 0.1 million electron volts (MeV) and thermal neutrons comprising neutrons exhibiting an energy less than about 0.68 electron volts (eV);producing a region of the neutron absorber proximate to the at least one sample material exhibiting neutron radiation having a fast-to-thermal neutron ratio of at least 15 by absorbing a portion of the thermal neutrons with at least one material forming the neutron absorber;flowing a coolant through a plurality of discrete channels extending through an entirety of the neutron absorber along a longitudinal axis thereof remote from the plurality of bores formed in the neutron absorber; andremoving heat from the neutron absorber with the coolant. 11. The method of claim 10, wherein positioning a neutron absorber comprises positioning the neutron absorber formed from a hafnium and aluminum composite material. 12. The method of claim 5, further comprising forming the neutron absorber from a powder mixture comprising hafnium and aluminum. 13. The method of claim 1, further comprising flowing a coolant through an annulus formed in the neutron absorber extending around at least one sample material. 14. The method of claim 1, wherein positioning a plurality of sample materials in a neutron absorber further comprises disposing a temperature control gas comprising at least one of helium and neon in each annulus formed between each jacket and each bore. 15. The method of claim 1, further comprising disposing the heat sink within a pressure tube. 16. The method of claim 15, wherein disposing the heat sink within a pressure tube comprises positioning the heat sink within the pressure tube to form a cooling annulus between the heat sink and the pressure tube. 17. The method of claim 15, wherein disposing the heat sink within a pressure tube comprises disposing the pressure tube within an envelope tube. 18. The method of claim 17, wherein disposing the heat sink within a pressure tube further comprises positioning the pressure tube within the envelope tube to form an annulus between the pressure tube and the envelope tube. 19. The method of claim 18, wherein disposing the heat sink within a pressure tube further comprises disposing helium within the annulus formed between the pressure tube and the envelope tube.