Scalable metamaterial thermally sprayed catalyst coatings for nuclear reactor high temperature solid oxide steam electrolysis (METASIS)
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The UK government has set an ambitious target of reaching net-Zero by 2050. Hydrogen has been considered to the energy vector to meet the target. However, a step change in technology is needed to produce enough green hydrogen to meet the target. One of the most promising new avenues for green hydrogen production is to combine the development of a highly active electrode layers for solid oxide steam electrolysis (SOSE) with the waste steam generated from nuclear power plant.
This project will develop an advance solution for zero emission hydrogen production by designing, fabricating, and testing thermally sprayed (air plasma spray) novel metasurface coatings of electrodes (tubular cell design) for solid oxide steam electrolysis (SOSE). While metasurface design for electrode is new, the tubular cell design has received increased attention in recent years, and among the different geometric design of electrode, the tubular design offers several advantages (e.g., alleviates issues associated with high temperature sealing as seals can be placed outside of high temperature zone, can have high active surface area, can be robust against thermal cycling, etc).
To achieve this, we need to benchmark the new design of electrolyser for high temperature (e.g., 700-900 C) steam deployment applications. The design will include structural (finite element analysis) and computational fluid dynamics analysis of the cell and develop understanding of its operational configurations with focus on structural and thermo-mechanical loads, incidental loads, and durability, including responses to the various loads (e.g., pressure fluctuations, temperature, and mechanical stresses). The material plays an important part in electrolysis, and therefore different electrode/electrolyte materials will be considered while manufacturing screen printing/spin coating method along with appropriate sintering processes. Following which, the cell (tubular samples as test coupon electrodes) will be fabricated using a combination of electrolyte. cathode, and anode from the materials list of choice using thermal spray (air plasma spray or APS) technique with cathode as metasurface at an industrial facility. We will then make solid oxide steam electrolyser prototype using the best design and materials choices. We will assess the overall viability of a modular design (a small container) with single tubular cell assembly. The single tubular assembly (or the electrolyser) will be tested at temperature as high as 900 C and will establish correlation between metasurface design and materials for optimum efficiency, including establishing mechanism of redox/transport processes and electro-chemical reactions. And finally, we will demonstrate the effect of materials, cell design and operational parameters on efficiency.
Developing electrolyser cells with enhanced hydrogen production and their scalable manufacturing can play an important role in enabling not only eco-friendly development but also cost-effective, reliable, and sustainable opportunities. This project has the potential to advance technology to produce green hydrogen and thus we will exploit the outcomes through a spin-out company or licensing to commercialise the product.
The Robert Gordon University | LEAD_ORG |
Nadimul Faisal | PI_PER |
Bahman Amini Horri | COI_PER |
Mamdud Hossain | COI_PER |
Anil Prathuru | COI_PER |
Qiong Cai | COI_PER |
Subjects by relevance
- Electrolysis
- Hydrogen
- Product development
- Nuclear power plants
- Production
- Design (artistic creation)
- Thermal spraying
Extracted key phrases
- Nuclear reactor high temperature solid oxide steam electrolysis
- Solid oxide steam electrolyser prototype
- Tubular cell design
- Scalable metamaterial
- Scalable manufacturing
- High temperature zone
- High temperature sealing
- Tubular design
- Air plasma spray
- Single tubular cell assembly
- Metasurface design
- Green hydrogen production
- New design
- Different geometric design
- Enhanced hydrogen production