SBIR-STTR Award

Important components within the fragmentation target system of the Rare Isotope Accelerator (RIA) - e.g., the permanent magnets of the EM pump of the liquid lithium target loop and the high temperature superconductor (HTS) windings of the superconducting magnets of the fragment separator - are subject to performance degradation by radiation. However, no data exists concerning the performance of these components under irradiation. Therefore, this project will perform irradiation testing in permanent magnets and high temperature superconductors, in order to identify the best combination of material types, irradiation facilities, and PIE (post-irradiation examination). Phase I will select the samples to be irradiated, the irradiation facility, and the post-irradiation examination techniques, and determine all aspects needed to irradiate, transport, examine, and analyse the selected samples. For those materials identified as suitable for the RIA application, the likelihood of achieving the production levels needed for the RIA will be assessed and suppliers will be identified.

Commercial Applications and Other Benefits as described by the awardee:
The irradiation data should be of value to commercial users of both permanent magnets and HTS, and the uncertainty of using these materials in the presence of radiation fields would be reduced. For the RIA, the information would allow the design of the fragmentation target system to move foreward with the assurance that the selected materials for the system would have predictable lifetime and performance under the anticipated operating conditions

The fragmentation target and separator of a next generation Radioactive Beam Facility will have several radiation sensitive components. The most sensitive are the pump for the liquid lithium target and the superconducting magnets. These elements utilize permanent magnet and superconducting cable materials that have not been fully characterized in terms of their long-term performance in high radiation environments. Hence, a facility is needed to carry out irradiations of various candidate materials, in order to reduce uncertainties and lead to a robust and cost-effective design for these components. This project will develop technology for the irradiation of high temperature superconductor, low temperature superconductor, and samarium cobalt permanent magnet material under strictly controlled conditions. The irradiations will be performed under environmental conditions that can be directly correlated with the conditions that will exist in the Radioactive Ion Beam facility. Phase I performed an initial simulation of radiological environments, as a basis for the choice of irradiation facilities. Candidate materials were identified and selected based on their appropriateness for the application and their commercial availability. Also, an initial design of a cryostat that can deliver the required temperature for irradiation to the samples was completed. During Phase II, a detailed design will be completed, and the cryostat will be procured. Then, superconductors and permanent magnets will be irradiated, data will be collected, and the results will be summarized. Commercial Application and Other Benefits as described by the awardee: The technology should provide a systematic way of performing irradiation at cryogenic temperature. The scientific community would benefit by having an apparatus available for irradiation testing at a reasonable cost