Hydrogen separation with dense ceramic membranes is non-galvanic, i.e. it does not require any electrode or an external power supply to drive the separation, and the hydrogen selectivity is almost 100% because the membrane contains no interconnected p...
Hydrogen separation with dense ceramic membranes is non-galvanic, i.e. it does not require any electrode or an external power supply to drive the separation, and the hydrogen selectivity is almost 100% because the membrane contains no interconnected porosity. In this study, a mixed proton-electron conducting perovskite made from BaCe<SUB>0.9</SUB>Y<SUB>0.1</SUB>O<SUB>3-δ</SUB> (BCYO) was prepared using a solid-state reaction, whereas a rapidly solidified Zr-based alloy (RSZ) was obtained via a melt-spinning process at a specified cooling rate. Finally, the BCYO/RSZ composite membrane was successfully fabricated by aerosol deposition (AD) at room temperature. The powders and composite membranes were characterized by high-temperature X-ray diffraction (HTXRD), particle size analysis (PSA), scanning electron microscopy (SEM), and X-ray elemental mapping (XRM). The hydrogen permeability of the dense BCYO/RSZ composite membrane was measured with the change of temperature. Under a pure hydrogen atmosphere at 773 K-1073 K, the BCYO/RSZ composite membrane exhibited higher permeability compared with the sole BCYO membrane over the entire investigated temperature range.