Patent Number: 
Section: claims

1. A radiation attenuation shield comprising:an attenuation layer formed from a composition comprising20 to 85 percent by volume of a polymer; and5 to 55 percent by volume of a radiation attenuating material,wherein the radiation attenuating material is dispersed within the polymer;a first magnetic material layer; anda second magnetic material layer, wherein the first and second magnetic material layers encase the attenuation layer. 2. The radiation attenuation shield of claim 1, wherein the radiation attenuating material comprises at least one component of iron, tungsten, bismuth, bismuth oxide, lead, boron carbide, and aluminum trihydrate. 3. The radiation attenuation shield of claim 1, wherein the radiation attenuating material comprises two or more components of iron, tungsten, bismuth, bismuth oxide, lead, boron carbide, and aluminum trihydrate. 4. The radiation attenuation shield of claim 1, wherein the radiation attenuating material is tungsten. 5. The radiation attenuation shield of claim 1, wherein the radiation attenuating material is iron. 6. The radiation attenuation shield of claim 1, wherein the polymer is a liquid silicone rubber that is catalyzed to a flexible solid. 7. The radiation attenuation shield of claim 1, wherein the magnetic material comprises at least one of a rare-earth metal alloy, ferrite, and iron powder. 8. The radiation attenuation shield of claim 1, wherein the magnetic material comprises at least two of a rare-earth metal alloy, ferrite, and iron powder. 9. The radiation attenuation shield of claim 1, wherein the radiation attenuating material and magnetic material comprises a powder of particles no larger than −60 mesh. 10. The radiation attenuation shield of claim 1, wherein the radiation attenuation ability of the radiation attenuation shield is at least 19 percent. 11. The radiation attenuation shield of claim 1, wherein the magnetic material of the radiation attenuation shield has a flat attractive force of at least 700 gauss and a closing force of at least 1400 gauss. 12. The radiation attenuation shield of claim 1, wherein the attenuation layer further comprises a magnetic material. 13. The radiation attenuation shield of claim 1 further comprising a first end portion comprising primarily magnetic material. 14. The radiation attenuation shield of claim 13 further comprising a second opposing end portion also comprising primarily said magnetic material. 15. A radiation attenuation shield comprising 10 to 70 percent by volume of a magnetic material, 5 to 55 percent by volume of a radiation attenuating material, and 20 to 85 percent by volume of a polymer. 16. The radiation attenuation shield of claim 15, wherein the radiation attenuating material is chosen from the group of iron, tungsten, bismuth, bismuth oxide, lead, boron carbide, and aluminum trihydrate. 17. The radiation attenuation shield of claim 15, wherein the radiation attenuating material comprises tungsten. 18. The radiation attenuation shield of claim 15, wherein the radiation attenuating material comprises iron. 19. The radiation attenuation shield of claim 15, wherein the radiation attenuating material comprises a mixture of tungsten and iron. 20. The radiation attenuation shield of claim 15, wherein the polymer is a liquid silicone rubber that is catalyzed to a flexible solid. 21. The radiation attenuation shield of claim 15, wherein the magnetic material comprises at least one of a rare-earth metal alloy, ferrite, and iron powder. 22. The radiation attenuation shield of claim 15, wherein the magnetic material comprises at least two of a rare-earth metal alloy, ferrite, and iron powder. 23. The radiation attenuation shield of claim 15, wherein the radiation attenuating material and magnetic material comprises a powder of particles no larger than −60 mesh. 24. The radiation attenuation shield of claim 15, wherein the radiation attenuation ability of the radiation attenuation shield is at least 19 percent. 25. The radiation attenuation shield of claim 15, wherein the magnetic material of the radiation attenuation shield has a flat attractive force of at least 700 gauss and a closing force of at least 1400 gauss. 26. The radiation attenuation shield of claim 15, wherein the radiation attenuating material and the magnetic material are dispersed within the polymer to form an attenuation layer. 27. The radiation attenuation shield of claim 26 further comprising a magnetic material layer positioned adjacent to the attenuation layer. 28. The radiation attenuation shield of claim 26 further comprising a magnetic material layer that encases the attenuation layer. 29. A method of manufacturing a radiation attenuation shield comprising the steps of:combining 20 to 85 percent by volume of a polymer, 5 to 55 percent by volume of a radiation attenuating material, and 10 to 70 percent by volume of a magnetic material to create a mixture;inserting said mixture into a mold;allowing said mixture to solidify to create a solidified mixture; andremoving said solidified mixture from said mold. 30. The method of claim 29 further including the step of curing said mixture. 31. The method of claim 29 further including the step of combining said polymer with a catalyst. 32. A system for attenuating radiation including the steps ofproviding a radiation attenuation shield comprising 20 to 85 percent by volume of a polymer, 5 to 55 percent by volume of a radiation attenuating material, and 10 to 70 percent by volume of a magnetic material;securing said radiation attenuation shield to a structure to limit radiation exposure surrounding said system. 33. The system of claim 32 wherein said structure radiates radiation and said radiation attenuation shield limits radiation from exiting said shield.