| People | Locations | Statistics |
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| Naji, M. |
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| Motta, Antonella |
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| Aletan, Dirar |
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| Mohamed, Tarek |
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| Ertürk, Emre |
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| Taccardi, Nicola |
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| Kononenko, Denys |
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| Petrov, R. H. | Madrid |
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| Alshaaer, Mazen | Brussels |
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| Bih, L. |
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| Casati, R. |
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| Muller, Hermance |
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| Kočí, Jan | Prague |
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| Šuljagić, Marija |
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| Kalteremidou, Kalliopi-Artemi | Brussels |
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| Azam, Siraj |
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| Ospanova, Alyiya |
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| Blanpain, Bart |
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| Ali, M. A. |
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| Popa, V. |
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| Rančić, M. |
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| Ollier, Nadège |
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| Azevedo, Nuno Monteiro |
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| Landes, Michael |
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| Rignanese, Gian-Marco |
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Khajavi, Peyman
Technical University of Denmark
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (11/11 displayed)
- 2024High-temperature degradation of tetragonal zirconia in solid oxide fuel and electrolysis cells:A critical challenge for long-term durability and a solutioncitations
- 2024Mitigating low-temperature hydrothermal degradation of 2 mol% yttria stabilised zirconia and of 3 mol% yttria stabilised zirconia/nickel oxide by calcium oxide co-doping and two-step sinteringcitations
- 2024High-temperature degradation of tetragonal zirconia in solid oxide fuel and electrolysis cellscitations
- 2024A solid oxide cell resistant to high-temperature isothermal degradation
- 2022Planar proton-conducting ceramic cells for hydrogen extractioncitations
- 2022Planar proton-conducting ceramic cells for hydrogen extraction:Mechanical properties, electrochemical performance and up-scalingcitations
- 2020(Invited) Advanced Alkaline Electrolysis Cells for the Production of Sustainable Fuels and Chemicals
- 2020Double Torsion testing of thin porous zirconia supports for energy applications: Toughness and slow crack growth assessmentcitations
- 2018Improving the mechanical properties and stability of solid oxide fuel and electrolysis cells
- 2018A Ba-free sealing glass with a high CTE and excellent interface stability optimized for SOFC/SOEC stack applicationscitations
- 2018A Ba-free sealing glass with a high CTE and excellent interface stability optimized for SOFC/SOEC stack applicationscitations
Places of action
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article
(Invited) Advanced Alkaline Electrolysis Cells for the Production of Sustainable Fuels and Chemicals
Abstract
<jats:p>Amongst the different electrolysis technologies, alkaline electrolysis (AE) stands out as the most well established for large-scale electrolytic hydrogen production, with commercially available multi-MW units combined in plants of 100s of MW and operated for decades. Besides proven reliability and availability, a key advantage of AE over alternative technologies when it comes to large-scale deployment is the relatively abundant and inexpensive materials it relies on. Nevertheless, AE suffers from relatively poor performance in terms of production rate and efficiency when compared to proton exchange membrane electrolysis (PEME) and solid oxide electrolysis (SOE).</jats:p><jats:p>One of the main reasons is associated with the sluggish hydrogen evolution reaction (HER) kinetics in alkaline environment [1]. Recent improvements in HER catalysts, have reduced the HER kinetics difference between alkaline and acidic environment. Furthermore, the far lower price of these catalysts (e.g. Ni, Ni<jats:sub>1-x</jats:sub>Mo<jats:sub>x</jats:sub>) compared to Pt, allow for much higher catalyst loadings, which can circumvent this challenge in conjunction with the much higher ionic conductivity of concentrated aqueous KOH as compared to PEME and SOE electrolytes. Taking full advantage of this opportunity requires a careful optimization of the AE electrode microstructure to achieve both a high electrochemically active surface area in close proximity to the separator as well as macro-porosity to enable gas evolution with minimal blocking of the active area. This was attempted here by applying high surface area catalytic coatings of Ni and Ni<jats:sub>1-x</jats:sub>Mo<jats:sub>x</jats:sub> on porous conducting supports with varying macro-pore structure. Furthermore, a finite element multi-physics simulation model was employed to provide further insight and guidance to the microstructural optimization effort.</jats:p><jats:p>Raising the operating temperature offers an additional means to drastically improve performance, as both ionic transport and reaction kinetics are strongly activated with temperature [2]. The development of a corrosion resistant ceramic separator [3] has enabled a novel concept of alkaline electrolysis cells operating at 200-250 °C and 20-50 bar [4,5], showing pronounced thermal activation, and achieving a current density of up to 3.75 A cm<jats:sup>-2</jats:sup> at a cell voltage of 1.75 V at 200 °C and 20 bar [6]. The feasibility and promise of this concept, as well as the challenges that lie ahead are also discussed.</jats:p><jats:p>[1] V. R. Stamenkovic, D. Strmcnik, P. P. Lopes and N. M. Markovic, <jats:italic>Nature Materials</jats:italic>, 2017, <jats:bold>16</jats:bold>, 57–69.</jats:p><jats:p>[2] M. H. Miles, G. Kissel, P. W. T. Lu and S. J. Srinivasan, <jats:italic>J. Electrochem. Soc.</jats:italic>, 1976, <jats:bold>123</jats:bold>, 332-336.</jats:p><jats:p>[3] F. Allebrod, C. Chatzichristodoulou, P. L. Mollerup and M. B. Mogensen, <jats:italic>Int. J. Hydrogen Energy</jats:italic>, 2012, <jats:bold>37</jats:bold>, 16505-16514.</jats:p><jats:p>[4] F. Allebrod, C. Chatzichristodoulou and M. B. Mogensen, <jats:italic>J. Power Sources</jats:italic>, 2013, <jats:bold>229</jats:bold>, 22–31.</jats:p><jats:p>[5] F. Allebrod, C. Chatzichristodoulou and M. B. Mogensen, <jats:italic>J. Power Sources</jats:italic>, 2014, <jats:bold>255</jats:bold>, 394-403.</jats:p><jats:p>[6] C. Chatzichristodoulou, F. Allebrod and M. B. Mogensen, <jats:italic>J. Electrochem. Soc.</jats:italic>, 2016, <jats:bold>163</jats:bold>, F3036-F3040.</jats:p>