Patent Number: 
Section: claims

1. A method of irradiating a material in an elution capsule, the elution capsule including,a tube with a first end portion having a first inside diameter, a second end portion having a second inside diameter,a singular first opening in the first end portion and a singular second opening in the second end portion, the first and second openings facing opposing directions and being about collinear with a longitudinal centerline of the tube,a middle portion having an inside diameter smaller than the inside diameters of the first and second end portions,the middle portion being between the first end portion and configured to hold the material,an interface between the first end portion and the middle portion forms a first shoulder and an interface between the second end portion and the middle portion forms a second shoulder,a first washer inside the first end portion contacting the first shoulder,a first filter inside the first end portion contacting the first washer,a second filter inside the first end portion contacting the first filter, the first filter being located between the first washer and the second filter,a first end cap sealing the first opening,a second washer inside the second end portion contacting the second shoulder,a third filter inside the second end portion contacting the second washer,a fourth filter inside the second end portion contacting the third filter, the third filter being located between the second washer and the fourth filter, anda second end cap sealing the second opening, the method comprising:placing the material in the middle portion of the elution capsule;placing the elution capsule in a neutron flux source; andirradiating the capsule and the material in the neutron flux source. 2. The method of claim 1, wherein the material includes one of titanium molybdate, zirconium molybdate, titanium tungstenate, and zirconyl tungstenate. 3. A method of eluting a material comprising:placing a sealed elution capsule enclosing the material into a nuclear reactor, the elution capsule having first and second end portions with a singular, sealed first opening in the first end portion and a singular, sealed second opening in the second end portion, the first and second openings facing opposing directions and being about collinear with a longitudinal centerline of the elution capsule;irradiating the sealed elution capsule and the material in a reactor;removing the sealed elution capsule and irradiated material from the reactor; andperforming an elution step by puncturing the first opening of the elution capsule with a needle to supply a solution to the elution capsule and puncturing the second opening with a needle to provide a vacuum to draw the solution through the irradiated material to collect the eluant. 4. The method of claim 3, further comprising:applying a first adhesive layer on an inner surface of a first flexible material that forms a seal over the first opening and a second adhesive layer on an inner surface of a second flexible, material, that forms a seal over the second opening. 5. The method of claim 3, wherein the material is one of titanium molybdate, zirconium molybdate, titanium tungstenate, and zirconyl tungstenate and the solution is one of distilled water, deionized water, saline, oxidizers, acids, or bases. 6. The method of claim 3, wherein the sealed elution capsule includes a multidiameter tube with the first end portion having a first inside diameter, the second end portion having a second inside diameter, and a middle portion between the first end portion and the second end portion having an inside diameter smaller than the inside diameters of the first and second end portions, wherein an interface between the first end portion and the middle portion forms a first shoulder and an interface between the second end portion and the middle portion forms a second shoulder. 7. The method of claim 6, further comprising:placing a first washer inside the first end portion to contact the first shoulder;placing a first filter inside the first end to contact the first washer;placing a second filter inside the first end such that the first filter is between the first washer and the second filter;applying epoxy to a first end cap;inserting the first end cap in the first end portion to seal the first opening;placing the material into the middle portion of the multidiameter tube, wherein the material enters the middle of the multidiameter tube from the second end portion;placing a second washer inside the second end portion to contact the second shoulder;placing a third filter inside the second end portion to contact the second washer;placing a fourth filter inside the second end portion such that the third filter is between the second washer and the fourth filter; andapplying epoxy to a second end cap;inserting the second end cap in the second end portion to seal the second opening;applying epoxy to internal surfaces of a first non-hardening flexible seal;placing the first non-hardening flexible seal over the first opening after the irradiation step to form an extra seal for sealing the first opening of the capsule;applying epoxy to internal surfaces of a second non-hardening flexible seal; andplacing the second non-hardening flexible seal over the second opening after the irradiation step to form an extra seal for sealing the second opening of the capsule. 8. The method of claim 2, further comprising:removing the elution capsule from the neutron flux source;eluting the elution capsule using a solution that is one of distilled water, deionized water, saline, oxidizers, acids or bases.