Abstract
Stable composition and catalytic activity of surfaces are among the key requirements for materials employed in energy storage and conversion devices, such as solid oxide fuel cells (SOFCs). Perovskite oxides that serve as cathode in SOFCs suffer from segregation of the aliovalent substitutional cations and the formation of an inert, non-conductive phase at the surface. Here, we demonstrate that the surface of the state-of-the-art SOFC cathode material La0.8Sr0.2MnO3 (LSM) is stabilized against the segregation of Sr at high temperature by submonolayer coverages of Hf. The Hf is vapor-deposited onto the LSM thin film surface by e-beam evaporation. Using in situ near-ambient pressure X-ray photoelectron spectroscopy (NAP-XPS), we analyze the surface composition of LSM thin films. Half the LSM surface was kept as-prepared, and half was Hf-modified, for a direct comparison of untreated and Hf-treated regions on the same sample. The formation of a binary SrOx surface species is quantified as descriptor for surface degradation. The onset of Sr segregation is observed at 450 °C on the bare LSM, followed by a substantial advance at 550 °C. Hf-treated regions of the same LSM surface exhibit significantly less Sr surface segregation at 450–550 °C. We interpret this stabilization imparted by Hf to arise from the suppression of the electrostatic attraction of Sr2+ cations to surface oxygen vacancies. Doping the surface layer with Hf, that has a higher affinity to oxygen, reduces this attraction by decreasing the surface oxygen vacancy concentration. In doing so, the use of physical vapor deposition highlights the direct role of the metal species in this system and excludes artifacts that could be introduced via chemical routes. The present work demonstrates this stabilizing effect of Hf on the surface of LSM, broadening the relevance of our prior findings on surface metal doping of other perovskite oxides.
Highlights
Catalytic materials for energy storage and conversion have to satisfy challenging requirements, including high catalytic activity, compatibility with multicomponent materials, and long-term stability under demanding operating conditions
Diffusion, or evolution of oxygen, perovskite oxides (ABO3) are considered state-ofthe-art materials owing to their versatility in composition and electrical properties, structural stability, and compatibility with many other relevant compounds in energy applications.[1−3] As a result of their desirable electrocatalytic properties, they are widely employed in devices such as solid oxide fuel cells (SOFCs),[4−10] gas separation membranes,[11] as well as in gas conversion, reformation,[12] and syngas production.[13]
The electrochemical performance of LSM as a cathode material is affected by structural and compositional variations occurring at the surface at conditions relevant to SOFC operation, for example under polarization.[25−27] In particular, segregation and phase separation of the Sr dopant is a known problem limiting their surface stability and the rate of oxygen exchange.[28−37] Here, we present an approach to enhance the stability of the surface chemistry of LSM at elevated temperatures
Summary
Catalytic materials for energy storage and conversion have to satisfy challenging requirements, including high catalytic activity, compatibility with multicomponent materials, and long-term stability under demanding operating conditions. It is shown in prior work that at high temperatures in an oxidizing atmosphere, the Sr dopant cations segregate to the surface, where they accumulate and form an inert oxide layer. These Sr-rich precipitates are non-conductive (electronically and ionically)[38] and inhibit access of gas Received: October 27, 2020 Revised: January 27, 2021 Published: February 8, 2021
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