SBIR-STTR Award

Wide angle neutron analyzers require large volumes of polarized 3He gas that must maintain very high polarization. As these instruments have increased in size, they have outstripped 3He polarization capacity, shortening the run times and adversely affecting. A very high productivity source of polarized 3He and a method for flushing these instruments is needed for the next generation of neutron analyzers. We propose to develop an analyzer system that mates our large volume, low cost 3He polarizer to a large volume analyzer, so that the instrument may be frequently refilled and therefore be kept online. This proposal is to develop the gas handling technology to accomplish this. Commercial Applications and Other

Benefits:
The direct benefit of this project is to enable new experiments and increase data rates in the neutron scattering experiments. Since neutron scattering is widely used in materials science research, increasing the analyzer availability would increase the availability for the beam for commercial research. There is a small but important market for this technology at nuclear physics laboratories around the world for applications in addition to neutron scattering. Also the gas handling technology proposed here may be important in the growing field of hyperpolarized gas MRI for medical imaging.

The United States and several other countries are investing in new neutron scattering facilities as well as upgrading existing ones due to their promise for fundamental and applied research that can catalyze advances in energy, telecommunications, manufacturing, plastics, transportation, biotechnology, and health. The performance of one new type of instrument, the wide-angle polarized neutron spectrometer, is severely constrained by the volume of polarized3 He gas that can be produced and the level of polarization that it can maintain. Currently 3He polarizers produced in Europe based on Metastability Exchange Optical Pumping dominate the international market, with existing installations in Germany and France and two multimillion dollar contracts recently closed for ISIS in England and ANSTO in Australia. Even those systems have limitations in capacity and reliability, leading developers of new wide-angle spectrometers, such as the TOPAS group at Jlich, to seek an alternative with greater capacity, higher polarization, and better reliability. In an ongoing parallel project, our team developed a large-scale 3He polarizer based on Hybrid-alkali Spin Exchange Optical Pumping. By illuminating a large 8.5 liter glass polarizer cell inside a pressure vessel with a 1.2 kW laser we demonstrated spin-up rates of 20% per hour for 50 STP liters, a world record. We recently upgraded that polarizer with a custom-built 2.5 kW spectrally-narrowed laser and a fully integrated support infrastructure. Testing of new monolithic glass cells in this upgraded polarizer is imminent. In Phase 1 of this project, we demonstrated feasibility for utilizing this large-scale 3He polarizer to allow automated filling and emptying of a large analyzer with minimal polarization losses. In particular, we proposed and accomplished four objectives: we designed and had built a non-ferrous vacuum pump capable of evacuating a 40 liter analyzer volume in 15 minutes with minimal polarization loss. We operated the compressor, demonstrating it can transfer helium from 100 torr to 8000 torr, simulating the required evacuation of the analyzer volume back into the polarizer. We developed a sapphire orifice throttle and installed it and the compressor in a rig for testing their polarization preserving properties. We began characterizing polarization losses using an integrated NMR system. These substantial accomplishments within a nine- month Phase 1 project give confidence that the technical challenges of assembling a high- polarization, low-loss, long-running prototype will be accomplished within our Phase 2 plan. Our overall plan seeks routine operation of a 40 liter neutron analyzer with average polarization exceeding 75%, a challenging goal demanded by the science. Since our exotic pump arrived just as Phase I ended, our first aim for Phase II is a thorough study of the existing setup. We will also extend our archival measurements of surface relaxivity to various metal, ceramic, and plastic materials to guide our choices for use in the final pumping system, transfer lines, valves, and orifices. Our second aim is to improve our polarizer. We will develop materials processing techniques that will allow our cells to be blown from GE180, and retrofit our laser with dedicated components that achieve 2.5kW with 0.15nm line width. Our third aim is to incorporate new subsystems and implement process automation that will be essential for routine operation of a large-scale 3He polarizer and wide-angle neutron analyzer. Commercial Applications and Other

Benefits:
We estimate a market size of a dozen large scale 3He polarizer-analyzer systems for fundamental and applied physics research over the next decade, with synergistic benefits in pediatric lung imaging.