Benchmarking the yttrium content in the low temperature/low humidity electrical properties of yttrium-doped barium cerate

Yttrium-doped barium cerate (BCY) is one of the best proton-conducting ceramics to be used in fuel cells/electrolyzers at intermediate temperatures, due to its high hydration enthalpy and high conductivity. Nonetheless, it has commonly been discarded for these applications due to its instability in the presence of carbonaceous and humidified atmospheres. A recent work has addressed this issue, by suggesting the use of this material in very low water vapor partial pressures (p(H2O) similar to 10(-4) atm) [Electrochimica Acta 334 (2020) 135625] and at low temperatures (T <= 400 degrees C). Under these conditions, BCY can still offer pure protonic conductivity while also offering suitable stability. In the current work, we provide a comprehensive analysis of the effects of the acceptor dopant concentration (Y2O3) in the structural, microstructural, and electrical properties in a wide compositional series of BaCe1-xYxO3-delta (x = 0.05, 0.10, 0.20 and 0.30) at low levels of humidity in the low temperature range (100-400 degrees C). The results show that BaCe0.9Y0.1O3-delta (BCY10) offers the highest bulk conductivity in these conditions, while further increase in dopant concentration leads to impairment due to "proton trapping" effects. In contrast, the specific grain boundary conductivity increases with increasing dopant concentration due to a reduction of Schottky barrier height at the space-charge layer. We demonstrate that, by operating at very low temperatures (e.g., below 400 degrees C), the peak performing, BCY10 material can still operate at very low levels of water vapor partial pressure (p(H2O) similar to 10(-4) atm), where its stability can be maintained. This work paves the way for the optimization of this material, with a focus on utilizing low humidity levels and low temperatures, where it can offer a competitive advantage over that of the majority of other proton-conducting perovskites for potential applications operating under these conditions.