Abstract
The anodic oxygen evolution reaction (OER) has significant importance in many electrochemical technologies. In proton exchange membrane water electrolyzers it plays a pivotal role for electrochemical energy conversion, yet sluggish kinetics and the corrosive environment during operation still compel significant advances in electrode materials to enable a widespread application. Up-to-date Iridium is known as the best catalyst material for the OER in acidic media due to its relatively high activity and long-term stability. However, scarcity of iridium drives the development of strategies for its efficient utilization. One promising way would be the formation of mixtures in which the noble catalyst element is dispersed in the non-noble matrix of more stable metals or metal oxides. A promising valve metal oxide is TiOx, yet the degree to which performance can be optimized by composition is still unresolved. Thus, using a scanning flow cell connected to an inductively coupled plasma mass spectrometer, we examined the activity and stability for the OER of an oxidized Ir–Ti thin film material library covering the composition range from 20–70 at.% of Ir. We find that regardless of the composition the rate of Ir dissolution is observed to be lower than that of thermally prepared IrO2. Moreover, mixtures containing at least 50 at.% of Ir exhibit reactivity comparable to IrO2. Their superior performance is discussed with complementary information obtained from atomic scale and electronic structure analysis using atom probe tomography and x-ray photoelectron spectroscopy. Overall, our data shows that Ir–Ti mixtures can be promising OER catalysts with both high activity and high stability.
Highlights
With increasing environmental concerns, sustainable energy sources are anticipated to eventually replace traditional fossil fuels
Iridium, titanium, oxygen and carbon were found on the surface
For oxygen evolution reaction (OER) related applications the main research efforts were focused on reduction of the amount of the noble metal in the electrode without a significant decrease in electronic conductivity and reactivity [9]
Summary
Sustainable energy sources are anticipated to eventually replace traditional fossil fuels. Materials that catalyze water decomposition should provide high reactivity and maintain stability throughout long-time operation. This is especially crucial in case of the anodic oxygen evolution reaction (OER), due to the extremely corrosive acidic environment and the high potential required to drive this reaction [6,7,8]. A few materials are able to meet the necessary requirements to simultaneously provide sufficient reactivity and durability in harsh oxidizing conditions [9, 10] Those are oxides with metallic-type conductivity, among which only iridium oxides are currently used in acidic water electrolyzers [4, 11, 12]. The origin of the improved stability in such systems and the interplay between composition and activity-stability trends remains an open question
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