oxygen evolution reaction – Lightsources.org

Key mechanisms in amorphous iridium oxides for next-generation water electrolysis

2025/06/182025/06/20

A multidisciplinary team from institutions in Germany, Argentina, and Spain has revealed new understanding of amorphous hydrous iridium oxides (am-hydr-IrOx) and their role in sustainable energy production. Using advanced synchrotron techniques, the researchers monitored both electronic and geometric structures of these materials under real operating conditions. Their findings, published in Energy & Environmental Science, could lead to more efficient and durable catalysts for green hydrogen production.

Water electrolysis plays a crucial role in converting renewable energy from sources like wind and solar into hydrogen. A key challenge in this process is the oxygen evolution reaction (OER), which requires highly effective anode catalysts. While iridium-based materials are the gold standard for OER catalysts in proton exchange membrane water electrolyzers (PEM-WE), iridium’s scarcity raises significant concerns about their long-term scalability. Among the most promising candidates are amorphous hydrous iridium oxides (am-hydr-IrO_x), though their study with some wide-spread techniques, like x-ray diffraction, is challenging, because of their lack of long-range atomic order. Moreover, most structural models used to explain the limiting (electro)chemical mechanisms of am-hydr-IrO_x are based on ordered crystalline phases, making them inadequate for understanding amorphous materials.

A new study, published in Energy & Environmental Science, combines synchrotron-based characterization techniques with density functional theory (DFT) calculations to develop a comprehensive model for amorphous hydrous iridium oxides. The collaborative work involved researchers from Helmholtz Zentrum Berlin and the Fritz-Haber-Institut in Germany, and the ALBA Synchrotron. By investigating hydrous iridium oxide thin films (HIROFs), the researchers showed that iridium dissolution can occur spontaneously and is thermodynamically driven, and is not always a direct consequence of the oxygen evolution reaction (OER).

The team prepared HIROF thin films through controlled electrochemical oxidation of metallic iridium substrates using cyclic voltammetry. This process created a highly porous, hydrated am-hydr-IrOx with a disordered three-dimensional structure containing numerous edges and bulk defects. As revealed in the study, these features enhance OER activity, but they also contribute to material instability.

Ex situ characterization using cryo-TEM confirmed the amorphous and porous nature of the films. X-ray photoelectron spectroscopy (XPS) revealed hydroxyl groups and a progressive increase in iridium oxidation state with increasing film thickness. Electrochemical measurements helped define three distinct potential regimes-–pre-redox, redox and OER regimes—, which mark important transitions in the catalyst’s structural and electronic behavior.

To understand atomic-scale transformations, the researchers applied in situ and operando spectroscopic techniques at two synchrotron beamlines: KMC-3 at BESSY II (Germany) and NOTOS at ALBA. They performed in situ Ir L₃-edge X-ray absorption near-edge structure (XANES) and extended X-ray absorption fine structures (EXAFS) under electrochemical control to monitor changes in iridium oxidation state and Ir–O bond lengths. The results showed progressive oxidation and structural distortion as the applied potential increased. Operando Fixed Energy X-ray Absorption Voltammetry (FEXRAV) established a direct link between electronic transitions and electrochemical activity. Near-ambient pressure hard X-ray photoelectron spectroscopy (NAP-HAXPES) provided complementary surface-sensitive insights into oxidation states at hydrated conditions.

To explain their observations, the team developed a novel atomistic model — a hydrogen-terminated nanosheet structure — that departs from previous crystalline-based approaches. This model offers a more accurate representation of the amorphous phase and, when used in DFT simulations, revealed diverse reactive sites that affect OER activity and iridium dissolution differently.

The research established a dual-mechanistic framework where deprotonation and oxidation drive the OER pathway, while a separate, independent process leads to spontaneous Ir loss through defect formation. Both mechanisms exist simultaneously and evolve as the applied potential changes. When compared with operando EXAFS measurements, the simulated structures showed strong agreement, validating the model and identifying probable active sites and degradation pathways.

Read more on ALBA website

Green hydrogen: A cage structured material transforms into a performant catalyst

2025/04/172025/04/28

Clathrates are characterised by a complex cage structure that provides space for guest ions too. Now, for the first time, a team has investigated the suitability of clathrates as catalysts for electrolytic hydrogen production with impressive results: the clathrate sample was even more efficient and robust than currently used nickel-based catalysts. They also found a reason for this enhanced performance. Measurements at BESSY II showed that the clathrates undergo structural changes during the catalytic reaction: the three-dimensional cage structure decays into ultra-thin nanosheets that allow maximum contact with active catalytic centres. The study has been published in the journal ‘Angewandte Chemie’.

Hydrogen can be produced by electrolysis of water. If the electrical energy required for this process comes from renewable sources, this hydrogen is even carbon neutral. This ‘green’ hydrogen is seen as an important building block for the energy system of the future and is also needed in large quantities as a raw material for the chemical industry. Two reactions are crucial in electrolysis: hydrogen evolution at the cathode and oxygen evolution at the anode (OER). However, the oxygen evolution reaction in particular slows down the desired process. To speed up hydrogen production, more efficient and robust catalysts for the OER process need to be developed.

Clathrates, a structure build of cages

Currently, nickel-based compounds are considered to be good and inexpensive catalysts for the alkaline oxygen evolution reaction. This is where Dr. Prashanth Menezes and his team come in. ‘The contact between the active nickel centres and the electrolyte plays a crucial role in the efficiency of a catalyst,’ says the chemist. In conventional nickel compounds, this surface area is limited. ‘We therefore wanted to test whether nickel-containing samples from the fascinating class of materials known as clathrates could be used as catalysts’.

The materials are made of Ba₈Ni₆Ge₄₀ and were produced at the Technical University of Munich. Like all clathrates, they are characterised by a complex crystalline structure of polyhedral cages, in this case, formed by germanium and nickel, enclosing barium. This structure gives clathrates special properties that make them interesting as thermoelectrics, superconductors or battery electrodes. However, until now, no research group had considered of investigating clathrates as electrocatalysts.

Read more on HZB website

Image: The illustration shows schematically how nanothin sheets of nickel compounds are released from the clathrate structure, providing an extremely large surface area for the oxygen evolution reaction.

Credit: Hongyuan Yang/HZB/TUB

Green hydrogen: MXenes shows talent as catalyst for oxygen evolution

2024/09/092024/09/16

The MXene class of materials has many talents. An international team led by HZB chemist Michelle Browne has now demonstrated that MXenes, properly functionalised, are excellent catalysts for the oxygen evolution reaction in electrolytic water splitting. They are more stable and efficient than the best metal oxide catalysts currently available. The team is now extensively characterising these MXene catalysts for water splitting at the Berlin X-ray source BESSY II and Soleil Synchrotron in France.

Green hydrogen is seen as one of the energy storage solutions of the future. The gas can be produced in a climate-neutral way using electricity from the sun or wind by electrolytic water splitting. While hydrogen molecules are produced at one electrode, oxygen molecules are formed at the other. This oxygen evolution reaction (OER) is one of the limiting factors in electrolysis. Special catalysts are needed to facilitate this reaction. Among the best candidates for OER catalysts are, for example, nickel oxides, which are inexpensive and widely available. However, they corrode quickly in the alkaline water of an electrolyser and their conductivity also leaves much to be desired. This is currently preventing the development of low-cost, high-performance electrolysers.

MXene as catalysts

A new class of materials could offer an alternative: MXenes, layered materials made of metals, such as titanium or vanadium, combined with carbon and/or nitrogen. These MXenes have a huge internal surface area that can be put to fantastic use, whether for storing charges or as catalysts.

An international team led by Dr Michelle Browne has now investigated the use of MXenes as catalysts for the oxygen evolution reaction. PhD student Bastian Schmiedecke chemically ‘functionalised’ the MXenes by docking copper and cobalt hydroxides onto their surfaces. In preliminary tests, the catalysts produced in this way proved to be significantly more efficient than the pure metal oxide compounds. What’s more, the catalysts showed no degradation and even improved efficiency in continuous operation.

Read more on HZB website

Image: The surface of a Vanadium carbide MXene has been examined by Scanning Electron Microscopy. The beautiful structures are built by cobalt copper hydroxide molecules.

Credit: B. Schmiedecke/HZB

Green hydrogen: Perovskite oxide catalysts analysed in an X-ray beam

2024/01/092024/01/09

The production of green hydrogen requires catalysts that control the process of splitting water into oxygen and hydrogen. However, the structure of the catalyst changes under electrical tension, which also influences the catalytic activity. A team from the universities of Duisburg-Essen and Twente has investigated at BESSY II and elsewhere how the transformation of surfaces in perovskite oxide catalysts controls the activity of the oxygen evolution reaction.

In a climate-neutral energy system of the future, the sun and wind will be the main sources of electricity. Some of the “green” electricity can be used for the electrolytic splitting of water to produce “green” hydrogen. Hydrogen is an efficient energy storage medium and a valuable raw material for industry. Catalysts are used in electrolysis to accelerate the desired reaction and make the process more efficient. Different catalysts are used for hydrogen separation than for oxygen evolution, but both are necessary.

Perovskite oxide catalysts: inexpensive and with great potential

An interdisciplinary and international group of scientists from the University of Essen-Duisburg, the University of Twente, Forschungszentrum Jülich and HZB has now investigated the class of perovskite oxide catalysts for the oxygen evolution reaction in detail. Perovskite oxide catalysts have been significantly further developed in recent years, they are inexpensive and have the potential for further increases in catalytic efficiency. However, within a short time, changes appear on the surfaces of these materials which reduce the catalytic effect.

Read more on the HZB website

Image: Schematic side view of the transformed layer (light grey) on top of the perovskite film (green) grown on a substate (brown). (right) zoom-in of the side view of the transfromed layer together with spin density at the Ni sites from the density functional theory calculations.