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Hikita, Yasuyuki
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Topics
Publications (7/7 displayed)
- 2024A Cantaloupe‐Rind‐Inspired Nanostructured Textile Catalyst for Enhanced and Recoverable Performance in High‐Temperature Electrochemical Cells
- 2018Inhomogeneous barrier heights at dipole-controlled SrRuO 3 /Nb:SrTiO 3 Schottky junctionscitations
- 2018Strain Tuning in Complex Oxide Epitaxial Films Using an Ultrathin Strontium Aluminate Buffer Layercitations
- 2017Dielectric collapse at the LaAlO 3 /SrTiO 3 (001) heterointerface under applied electric fieldcitations
- 2016Defect-control of conventional and anomalous electron transport at complex oxide interfacescitations
- 2015Controlling band alignments by artificial interface dipoles at perovskite heterointerfacescitations
- 2011Direct imaging of the coexistence of ferromagnetism and superconductivity at the LaAlO3/SrTiO3 interfacecitations
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article
A Cantaloupe‐Rind‐Inspired Nanostructured Textile Catalyst for Enhanced and Recoverable Performance in High‐Temperature Electrochemical Cells
Abstract
<jats:title>Abstract</jats:title><jats:p>Electrodes with a maximal active site density are critical for high‐performance high‐temperature electrochemical cells (HTECs). One widely employed approach involves the use of porous nanostructures with a high surface‐to‐volume ratio. However, their active site densities inevitably decrease owing to particle aggregation induced at high temperatures, necessitating further development of electrode processing techniques. Taking Pt/yttria‐stabilized zirconia (YSZ) interface as a model system, a Pt nanostructured textile akin to the cantaloupe‐rind pattern with high mechanical integrity is fabricated. Application of an AC voltage to this textile electrode at an elevated temperature reduces the Pt particle size from submicron to 10–80 nm forming a nanocomposite with YSZ, accompanied by a 40‐fold increase in current density under high‐temperature water electrolysis conditions. Furthermore, the AC voltage application to a partially aggregated electrode restores its nano‐blended structure associated with the recovery of its activity. This technique is effective in counteracting particle aggregation on demand, providing an alternative approach to achieve high performance and extended lifetimes in HTECs.</jats:p>