Reducing noble metal loading and increasing specific activity of oxygen evolution catalysts are omnipresent challenges in proton exchange membrane (PEM) water electrolysis, which have recently been tackled by utilizing mixed oxides of noble and non-noble elements (e.g. perovskites, IrNiO x , etc.). However, proper verification of the stability of these materials is still pending. In this work dissolution processes of various iridium-based oxides are explored by introducing a new metric, defined as the ratio between amount of evolved oxygen and dissolved iridium. The so called Stability-number is independent of loading, surface area or involved active sites and thus, provides a reasonable comparison of diverse materials with respect to stability. Furthermore it can support the clarification of dissolution mechanisms and the estimation of a catalyst's lifetime. The case study on iridium-based perovskites shows that leaching of the non-noble elements in mixed oxides leads to formation of highly active amorphous iridium oxide, the instability of which is explained by participation of activated oxygen atoms, generating short-lived vacancies that favour dissolution. These insights are considered to guide further research which should be devoted to increasing utilization of pure crystalline iridium oxide, as it is the only known structure that guarantees a high durability in acidic conditions. In case amorphous iridium oxides are used, solutions for stabilization are needed.
Understanding the pathways of catalyst degradation during the oxygen evolution reaction is a cornerstone in the development of efficient and stable electrolyzers, since even for the most promising Ir based anodes the harsh reaction conditions are detrimental. The dissolution mechanism is complex and the correlation to the oxygen evolution reaction itself is still poorly understood. Here, by coupling a scanning flow cell with inductively coupled plasma and online electrochemical mass spectrometers, we monitor the oxygen evolution and degradation products of Ir and Ir oxides in situ. It is shown that at high anodic potentials several dissolution routes become possible, including formation of gaseous IrO3. On the basis of experimental data, possible pathways are proposed for the oxygen‐evolution‐triggered dissolution of Ir and the role of common intermediates for these reactions is discussed.
Combination of atom probe tomography, isotope-labelling and online electrochemical mass spectrometry provides direct correlation of atomic scale structure of Ir oxide catalysts with the mechanism of oxygen formation from the lattice atoms.
For a successful replacement of Pt,
tremendous efforts have hitherto
been made to develop high-performing Fe-N-C catalysts for the oxygen
reduction reaction (ORR) in polymer electrolyte membrane fuel cells
(PEMFCs). In comparison to the remarkable progress in activity, the
stability of Fe-N-C catalysts still remains critical, however. Fe
demetallation in acidic medium is hypothesized to be one critical
factor for the overall lifetime. In contrast to the general belief,
we herein demonstrate using an operando spectroscopic analysis that
catalytically inactive Fe particles exposed to acid electrolytes cannot
be fully removed by acid washing due to a relatively high open circuit
potential (ca. 0.9 VRHE) leading to the formation of insoluble
ferric species, whereas these particles dissolve under PEMFC operating
conditions (E
cathode < 0.7 VRHE) due to operando reduction to soluble ferrous cations. To overcome
this issue, we demonstrate two approaches: (i) synthesis of Fe-N-C
catalysts free of Fe particles and (ii) postsynthesis removal of exposed
Fe particles through the control of potential using an external potentiostat
or an internal reducing agent (i.e., SnCl2). Operando spectroscopic
analyses verified that Fe demetallation during a given voltammetric
protocol was dramatically decreased for both synthetically and postsynthetically
modified Fe-N-C catalysts, while the initial ORR activity did not
significantly change. However, all of these catalysts showed similar
performance decay over short-term PEMFC durability tests, demonstrating
the lack of a role played by ferrous cations leached from inactive
Fe particles on catalyst deactivation. This supports the view that
the activity is mainly imparted by FeN
x
C
y
moieties. Nevertheless, the presented
guidelines are generally applicable to the whole class of Fe-N-C catalysts
in order to minimize Fe demetallation in PEMFCs, which provides important
advances for the future design of stable electrocatalytic systems
for long-term operation.
Iridium is the main element in modern catalysts for the oxygen evolution reaction (OER) in proton exchange membrane water electrolyzers (PEMWE), which is predominantly due to its relatively good activity and tolerable stability in harsh PEMWE conditions. Limited abundance of iridium, however, poses limitations on widespread applications of these devices, in particular in the large scale conversion and storage of renewable energy. In this work we investigate if the electrocatalytic performance of iridium can be fine-tuned by thermal treatment of catalysts at different temperatures. The OER activity and the dissolution of two different iridium electrodes, viz. (a) flat metallic iridium surfaces prepared by electron beam physical vapor deposition (EBPVD) and (b) electrochemically prepared porous hydrous iridium oxide films (HIROF) are studied. The range of applied annealing temperatures is 100 • C-600 • C, with a general trend of decreasing activity and increasing stability the higher the temperature. Numerous peculiarities in the trend are however observed. These are discussed considering variations of oxide structure, morphology and electronic conductivity.
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