Patent Number: 051679124
Section: claims

1. An improved neutron reflecting supermirror comprising a plurality of stacked sets of bilayers of high and low neutron scattering materials, said materials deposited upon a substrate, one layer of each of said sets of bilayers consisting of a low neutron scattering material and the second layer of each of said sets of bilayers consisting of an alloy including nickel and a microstructure enhancing element having a high neutron scattering potential; and the thickness of each bilayer set is between 2 to 400 nanometers. 2. A neutron reflecting supermirror as recited in claim 1, wherein the microstructure enhancing element is carbon, and is present interstitially in the nickel alloy layer to modify the nickel crystal. 3. A neutron reflecting supermirror as recited in claim 2, wherein the percentage of carbon present in the nickel alloy layer is between 5 and 50 percent. 4. A neutron reflecting supermirror as recited in claim 3, wherein the percentage of carbon present in the nickel alloy layer is between 12 and 30 percent. 5. A neutron reflecting supermirror as in claim 4, wherein the nickel alloy layer of said sets of bilayers has the nominal composition Ni.sub.86 C.sub.14. 6. A neutron reflecting supermirror as in claim 4, wherein the nickel alloy layer of said sets of bilayers has the nominal composition Ni.sub.71 C.sub.28. 7. A neutron reflecting supermirror as in claim 2, wherein the substrate is selected from the group consisting of float glass, pyrex glass, silicon, and other boron containing glasses. 8. A neutron reflecting supermirror as in claim 2, wherein the number of stacked sets of bilayers is between 2 and 1000. 9. A neutron reflecting supermirror as in claim 8, wherein the number of stacked sets of bilayers is between 5 and 500. 10. A neutron reflecting supermirror as in claim 1, wherein the thickness of each set of bilayers is varied with respect to other sets of bilayers. 11. A neutron reflecting supermirror as in claim 2, further including a layer of material deposited between the substrate and the first of said sets of bilayers, said deposited layer fabricated from material selected from the the group consisting of nickel, nickel alloy, carbon and combinations thereof. 12. A neutron reflecting supermirror as in claim 2, further including a layer of nickel deposited atop the uppermost set of bilayers, said deposited layer fabricated from material selected for the group consisting of nickel, nickel alloy, carbon, and combinations thereof. 13. A neutron reflecting supermirror as in claim 1, wherein the low neutron scattering material is titanium.