@article{36210,
  author = {Zhikuan Zhu and Boxun Hu and Michael C Tucker},
  title = {Dynamic operation of metal-supported solid oxide electrolysis cells},
  abstract = {<p><span><span>Symmetric-structure metal-supported solid\&nbsp;<a class="topic-link" title="Learn more about oxide from ScienceDirect{\textquoteright}s AI-generated Topic Pages" href="https://www.sciencedirect.com/topics/materials-science/oxide-compound">oxide</a><span>\&nbsp;fuel cells and\&nbsp;<a class="topic-link" title="Learn more about electrolysis cells from ScienceDirect{\textquoteright}s AI-generated Topic Pages" href="https://www.sciencedirect.com/topics/engineering/electrolysis-cell">electrolysis cells</a>\&nbsp;(MS-SOFCs, MS-SOECs) offer several advantages over conventional solid oxide cells, including the use of inexpensive materials, high\&nbsp;</span></span><a class="topic-link" title="Learn more about mechanical strength from ScienceDirect{\textquoteright}s AI-generated Topic Pages" href="https://www.sciencedirect.com/topics/materials-science/mechanical-strength">mechanical strength</a>, and rapid ramp-up ability. Aggressive operation of MS-SOCs in fuel cell mode is well-established, including extremely fast start-up, redox tolerance, and imbalanced pressure. Here, we extend dynamic operation to MS-SOCs in SOEC mode with high steam content for both small button cells and a large rectangular cell, including: steam cycling, thermal cycling, redox cycling and power cycling. Steam cycling entailed switching between 3:97 and 50:50 steam:hydrogen ratio. For thermal cycling, the temperature was rapidly varied between 150\&nbsp;{\textdegree}C and 700\&nbsp;{\textdegree}C for 50 cycles. Redox cycling involved switching the steam side gas between 50 \% humidified H</span><span>2</span><span>\&nbsp;and 50 \% humidified N</span><span>2</span><span><span>\&nbsp;for 5 cycles. Power cycling was performed by operating the cell under variable\&nbsp;<a class="topic-link" title="Learn more about current density from ScienceDirect{\textquoteright}s AI-generated Topic Pages" href="https://www.sciencedirect.com/topics/chemistry/current-density">current density</a><span>, resulting in\&nbsp;<a class="topic-link" title="Learn more about cell voltage from ScienceDirect{\textquoteright}s AI-generated Topic Pages" href="https://www.sciencedirect.com/topics/engineering/cell-voltage">cell voltage</a>\&nbsp;between 1.3\&nbsp;V and 2.8\&nbsp;V.\&nbsp;</span></span><a class="topic-link" title="Learn more about Degradation rates from ScienceDirect{\textquoteright}s AI-generated Topic Pages" href="https://www.sciencedirect.com/topics/engineering/degradation-rate">Degradation rates</a><span>\&nbsp;for each testing strategy were compared to a baseline cell, and found to be similar. The excellent tolerance to dynamic operation increases confidence that MS-SOECs will be compatible with dynamic or intermittent\&nbsp;<a class="topic-link" title="Learn more about renewable resources from ScienceDirect{\textquoteright}s AI-generated Topic Pages" href="https://www.sciencedirect.com/topics/engineering/renewable-energy-resource">renewable resources</a>.</span></span></p>},
  year = {2024},
  booktitle = {International Journal of Hydrogen Energy},
  journal = {International Journal of Hydrogen Energy},
  series = {International Journal of Hydrogen Energy},
  volume = {59},
  pages = {316 - 321},
  month = {02/2024},
  issn = {03603199},
  url = {https://linkinghub.elsevier.com/retrieve/pii/S0360319924003859},
  doi = {10.1016/j.ijhydene.2024.01.345},
  language = {eng},
}