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Interface-engineering to boost the performance and durability of nickel-metal-supported reversible proton ceramic cells for power generation and hydrogen production

Chenzhao Liu, Bo Liu, Zhenfei Li, Cheng Li, Dong Yan, Jian Li, Lichao Jia

2025Journal of Advanced Ceramics14 citationsDOIOpen Access PDF

Abstract

The metal-supported reversible proton ceramic cell (MS-rPCC) combines the dual advantages of metal support and proton conduction. It can simultaneously achieve efficient low-temperature operation, high mechanical strength, and excellent thermal cycling stability. However, a critical challenge in MS-rPCC fabrication lies in the element diffusion from the metal support and the mismatch between the metallic and ceramic layers. To address this, a rationally designed pure Ni metallic support combined with a transition layer (80 wt.% NiO-20 wt.% BaZr<sub>0.1</sub>Ce<sub>0.7</sub>Y<sub>0.2</sub>O<sub>3-</sub><sub>δ</sub> (BZCY)) was introduced to engineer the interface, improving the strength and structural stability of MS-rPCC. The cell achieves a peak power density of 0.8 W cm<sup>-2</sup> in fuel cell (FC) mode at 650 °C and a current density of -1.25 A cm<sup>-2</sup> at 1.3 V in electrolysis cell (EC) mode. FC mode exhibits no significant degradation after 200 hours of operation, with a degradation rate of 0.02 mV h<sup>-1</sup>. The cell demonstrated exceptional stability during 100 h of reversible fuel cell/electrolysis cycling, thermal cycling, and rapid start-up test. This work provides a new approach for the commercialization and widespread adoption of MS-rPCC for low-temperature, high-performance power generation and hydrogen production.

Topics & Concepts

DurabilityMaterials scienceStructural materialCeramicNickelInterface (matter)HydrogenMetallurgyMetalHydrogen productionElectricity generationPower (physics)Composite materialChemistryCapillary numberQuantum mechanicsPhysicsCapillary actionOrganic chemistryAdvancements in Solid Oxide Fuel CellsHybrid Renewable Energy SystemsSolar Thermal and Photovoltaic Systems
Interface-engineering to boost the performance and durability of nickel-metal-supported reversible proton ceramic cells for power generation and hydrogen production | Litcius