Abstract
Hydrogen production via water electrolysis using solid oxide electrolysis cells (SOECs) has attracted considerable attention because of its favorable thermodynamics and kinetics. It is considered as the most efficient and low‐cost option for hydrogen production from renewable energies. By using proton‐conducting electrolyte (H‐SOECs), the operating temperature can be reduced from beyond 800 to 600 °C or even lower due to its higher conductivity and lower activation energy. Technical barriers associated with the conventional oxygen‐ion conducting SOECs (O‐SOECs), that is, hydrogen separation and electrode instability that is primarily due to the Ni oxidation at high steam concentration and delamination associated with oxygen evolution, can be remarkably mitigated. Here, a self‐architectured ultraporous (SAUP) 3D steam electrode is developed for efficient H‐SOECs below 600 °C. At 600 °C, the electrolysis current density reaches 2.02 A cm−2 at 1.6 V. Instead of fast degradation in most O‐SOECs, performance enhancement is observed during electrolysis at an applied voltage of 1.6 V at 500 °C for over 75 h, attributed to the “bridging” effect originating from reorganization of the steam electrode. The H‐SOEC with SAUP steam electrode demonstrates excellent performance, promising a new prospective for next‐generation steam electrolysis at reduced temperatures.
Highlights
Inspired by the merits of highly porous electrode and outstanding performance of PBSCF, we developed a novel self-architectured ultraporous (SAUP) 3D steam electrode consisting of hollow PBSCF fibers for water splitting reaction in this study
The fibers are hollow with an average inner diameter of 1–2 μm, allowing water molecules to further go inside the electrode fibers at operating temperatures
The detailed features of the hollow fibers are further revealed by scanning transmission electron microscopy (STEM)
Summary
Clear interface contacts between 3D steam electrode and BZCYYb electrolyte were observed in both X-ray microscopy (Figure 2a) and SEM (Figure 2c). These solid contacts consist of PBSCF particles from PVB/PBSCF suspension in bonding process, which moved through the frame gaps to the interface under the force of gravity to form a pier-like conjunction. The ultralarge porosity could benefit to the fast steam transfer within the steam electrode and subsequently enhance the steam electrolysis performance
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