An investigation into the isotopic separation of hydrogen in metals by pressure swing adsorption
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The current reaction mechanism favoured for commercial fusion in a Tokamak design is the deuterium-tritium (D-T) reaction. However, tritium is unstable and beta decays with a ~12 year half-life. This means that it needs to be stored safely, and carefully monitored. The Culham Centre for Fusion Energy (CCFE) operates a tritium handling facility and uses a bed of uranium metal to store approximately 50g of tritium. Once, a fusion campaign is underway, the regulatory requirements dictate a strict separation and isolation of the tritium isotope. With the advent of a new tritium campaign and the development of ITER and the DEMO design, now is an ideal time to further investigate other routes/materials that might improve current tritium separation capabilities.
This project is an investigation into the ability of various metallic materials to isotopically separate gaseous mixtures of hydrogen. A technique known as pressure swing adsorption/desorption will be used to investigate the separation behaviour and compare the performance of a variety of potential candidate materials. Optimum performance conditions of pressure and temperature will be determined for each metal, so that a proposition can be made for future hydrogen isotopic separation technology.
| University of Bristol | LEAD_ORG |
| Thomas Scott | SUPER_PER |
Subjects by relevance
- Isotopes
- Hydrogen
- Tritium
- Uranium
Extracted key phrases
- Current tritium separation capability
- Future hydrogen isotopic separation technology
- New tritium campaign
- Tritium handling facility
- Pressure swing adsorption
- Tritium isotope
- Current reaction mechanism
- Strict separation
- Separation behaviour
- Investigation
- Potential candidate material
- Uranium metal
- Metallic material
- Fusion campaign
- Tokamak design