Patent Number: 
Section: claims

1. A crystal monochromator comprising:a Ge crystal body, wherein at least a first region of the Ge crystal body comprises a mosaic structure having a mosaicity of between about 15 arcminutes to about 28 arcminutes and a slow neutron reflectivity of about 70%-89% at a rocking curve peak. 2. The crystal monochromator of claim 1, wherein the slow neutron reflectivity is about 75%-89% at the rocking curve peak. 3. The crystal monochromator of claim 1, wherein the Ge crystal body has a thickness of about 7-10 mm cut from a plastically deformed ingot. 4. The crystal monochromator of claim 1, wherein the mosaic structure is approximately uniform over the Ge crystal body. 5. The crystal monochromator of claim 1, wherein the Ge crystal body comprises:the first region having the mosaicity of between about 15-28 arcminutes; anda second region having a mosaicity of less than 15 arcminutes. 6. The crystal monochromator of claim 5, wherein the Ge crystal body comprises a continuous gradient of mosaicity between the first region and the second region along at least one axis. 7. The crystal monochromator of claim 5, wherein the second region has an approximately perfect crystal structure with a mosaicity of less than approximately 1 arcminute. 8. The crystal monochromator of claim 1, wherein the Ge crystal body comprises a plastically deformed Ge crystal with a planar orientation of (1,1,1). 9. A method of manufacturing a crystal monochromator, comprising:heating an approximately perfect Ge crystal having an original thickness of approximately 3-5 cm to a temperature of over about 850° C.;compressing the Ge crystal for a duration of approximately 1-5 minutes with a force of about 5-10 metric tons while the Ge crystal is maintained at the temperature of over about 850° C. to plastically deform the Ge crystal along an axis of the Ge crystal, wherein the compressing causes a plastic deformation of about 0.5%-1.5% of the original thickness; andslicing the Ge crystal to form a plurality of crystal monochromators, wherein at least a first region of each of the plurality of crystal monochromators has a first mosaicity value of between about 15-28 arcminutes and a slow neutron reflectivity of about 70%-89% at a peak rocking curve. 10. The method of claim 9, further comprising polishing a top and a bottom of the Ge crystal prior to the heating and compressing to cause the Ge crystal to have an approximately uniform thickness of 3-5 cm+/−5 μm. 11. The method of claim 9, wherein the Ge crystal comprises an approximately perfect Ge crystal with a planar orientation of (1,1,1). 12. The method of claim 9, further comprising:trimming at least about 7 mm off of a top of the Ge crystal after the compressing and before the slicing; andtrimming at least about 7 mm off of a bottom of the Ge crystal after the compressing and before the slicing;wherein slicing the Ge crystal comprises slicing a remainder of the Ge crystal perpendicular to the axis of the Ge crystal to form the plurality of crystal monochromators. 13. The method of claim 12, wherein each of the plurality of crystal monochromators has a thickness of about 7-9 mm. 14. The method of claim 9, wherein heating the Ge crystal to the temperature of over about 850° C. comprises:heating the Ge crystal to a temperature of about 855° C.-870° C.; andmaintaining the Ge crystal at the temperature of about 855° C.-870° C. for a period of at least 1 hour prior to compressing the Ge crystal. 15. The method of claim 9, wherein compressing the Ge crystal with the force of about 5-10 metric tons comprises:applying a first force to the first region of the Ge crystal to cause the first region to have the first mosaicity of between about 15-28 arcminutes; andapplying a second force to a second region of the Ge crystal to cause the second region to have a second mosaicity that is lower than the first mosaicity. 16. The method of claim 15, further comprising:shaping a top surface of the Ge crystal to cause the top surface to have a surface profile wherein the first region is thicker than the second region; andshaping a bottom surface of the Ge crystal to cause the bottom surface to have the surface profile. 17. The method of claim 15, further comprising:shaping a surface of a first metal die used to contact a top of the Ge crystal during compression to cause the surface of the first metal die to have a surface profile wherein a first region of the metal die is thicker than a second region of the metal die; andshaping a surface of a second metal die used to contact a bottom of the Ge crystal during the compression to cause the surface of the second metal die to have the surface profile. 18. A crystal monochromator manufactured by a process comprising:heating an approximately perfect Ge crystal having an original thickness of approximately 3-5 cm to a temperature of over about 850° C.;compressing the Ge crystal for a duration of approximately 1-5 minutes with a force of about 5-10 metric tons while the Ge crystal is maintained at the temperature of over about 850° C. to plastically deform the Ge crystal along an axis of the Ge crystal, wherein the compressing causes a plastic deformation of about 0.5%-1.5% of the original thickness; andslicing the Ge crystal to form a plurality of crystal monochromators, wherein at least a first region of each of the plurality of crystal monochromators has a first mosaicity value of between about 15-28 arcminutes and a slow neutron reflectivity of about 70%-89% at a rocking curve peak. 19. The crystal monochromator of claim 18, wherein the process further comprises:trimming at least about 7 mm off of a top of the Ge crystal after the compressing and before the slicing; andtrimming at least about 7 mm off of a bottom of the Ge crystal after the compressing and before the slicing;wherein slicing the Ge crystal comprises slicing a remainder of the Ge crystal perpendicular to the axis of the Ge crystal to form the plurality of crystal monochromators each having thicknesses of about 7-9 mm. 20. A crystal monochromator, comprising:a Ge crystal body comprising a first region with a first mosaicity value; andthe Ge crystal body comprising a second region with a second mosaicity value that is higher than the first mosaicity value and a slow neutron reflectivity of about 70%-89% at a rocking curve peak. 21. The crystal monochromator of claim 20, wherein the first region has an approximately perfect crystal structure with a mosaicity of less than about 1 arcminute and the second region has a mosaicity of less than about 40 arcminutes. 22. The crystal monochromator of claim 20, wherein the Ge crystal body comprises a continuous gradient of mosaicity between the first region and the second region along at least one axis. 23. The crystal monochromator of claim 22, wherein the first region is an inner circular region of the monochromator, wherein the second region is an outer circular region of the monochromator that is concentric with the inner circular region, and wherein the continuous gradient is a radial gradient between the inner circular region and the outer circular region.