Green hydrogen: Improving iridium catalysts with titanium oxides

Die Iridium-Atome (rot) sind in unterschiedliche Titanoxide eingebettet, die für mehr Stabilität sorgen. 

Die Iridium-Atome (rot) sind in unterschiedliche Titanoxide eingebettet, die für mehr Stabilität sorgen.  © Marianne van der Merwe

Anodes for the electrolytic splitting of water are usually iridium-based materials. In order to increase the stability of the iridium catalyst, a team at HZB and a group at HI-ERN have now produced a so-called material library: a sample in which the concentration of iridium and titanium oxides is systematically varied. Analyses of the individual sample segments at BESSY II in the EMIL laboratory showed that the presence of titanium oxides can increase the stability of the iridium catalyst significantly.

One option for storing energy from sun or wind is the production of “green” hydrogen by electrolysis. Hydrogen stores energy in chemical form and releases it again when burnt, producing no exhaust gases, only water. Today, iridium is the state-of-the-art catalyst for this reaction. However, iridium increasingly dissolves in the acidic environment of the electrolysis cell, so that the catalytic effect quickly wanes.

“We wanted to investigate whether the stability of the catalyst can be improved by adding different proportions of titanium oxide,” says Prof Dr Marcus Bär (HZB). Although titanium oxide is not catalytically active, it is very stable. “We had some indications that the presence of titanium oxide would have a positive effect on stability without influencing the catalytic effect of the iridium. But we also wanted to find out whether there is an ideal mixing ratio.”

The sample as a materials library

The sample was produced at the Helmholtz Institute Erlangen-Nuremberg for Renewable Energies (HI-ERN) in Prof Dr Olga Kasian’s team by sputtering titanium and iridium with locally varying compositions. It is a so-called thin-film materials library on which the iridium content varies from 20% to 70%

At BESSY II, the team used X-ray spectroscopic methods to analyse how the chemical structure changes depending on the iridium content of the mixed iridium-titanium oxide samples. Several effects played a role here: for instance, the presence of titanium suboxides (such as TiO and TiOx) improved the conductivity of the material. Another exciting result was that some of the titanium oxides dissolve faster in the aqueous electrolyte than iridium, creating micropores on the surface. This promoted the oxygen evolution reaction because more iridium atoms from the lower layers come into contact with the electrolyte.

The main effect, however, is that titanium oxides (TiO2, as well as TiO and TiOx) significantly reduce the dissolution of iridium. “In the sample with 30 % titanium added compared to a pure iridium electrode material, we saw an iridium resolution that was approximately 70 % lower,” says Marianne van der Merwe, who carried out the measurements as part of her doctorate with Marcus Bär.

High relevance for practical use

But how relevant are such results from laboratory research for industry? “If there are already established technologies, it’s always difficult to change anything at first,” says Marcus Bär. “But here we show how the stability of the anodes can be significantly increased with a manageable amount of effort.”

arö

  • Copy link

You might also be interested in

  • Nanoislands on silicon with switchable topological textures
    Science Highlight
    20.01.2025
    Nanoislands on silicon with switchable topological textures
    Nanostructures with specific electromagnetic patterns promise applications in nanoelectronics and future information technologies. However, it is very challenging to control those patterns. Now, a team at HZB examined a specific class of nanoislands on silicon with interesting chiral, swirling polar textures, which can be stabilised and even reversibly switched by an external electric field.
  • Lithium-sulphur pouch cells investigated at BESSY II
    Science Highlight
    08.01.2025
    Lithium-sulphur pouch cells investigated at BESSY II
    A team from HZB and the Fraunhofer Institute for Material and Beam Technology (IWS) in Dresden has gained new insights into lithium-sulphur pouch cells at the BAMline of BESSY II. Supplemented by analyses in the HZB imaging laboratory and further measurements, a new picture emerges of processes that limit the performance and lifespan of this industrially relevant battery type. The study has been published in the prestigious journal Advanced Energy Materials.
  • Largest magnetic anisotropy of a molecule measured at BESSY II
    Science Highlight
    21.12.2024
    Largest magnetic anisotropy of a molecule measured at BESSY II
    At the Berlin synchrotron radiation source BESSY II, the largest magnetic anisotropy of a single molecule ever measured experimentally has been determined. The larger this anisotropy is, the better a molecule is suited as a molecular nanomagnet. Such nanomagnets have a wide range of potential applications, for example, in energy-efficient data storage. Researchers from the Max Planck Institute for Kohlenforschung (MPI KOFO), the Joint Lab EPR4Energy of the Max Planck Institute for Chemical Energy Conversion (MPI CEC) and the Helmholtz-Zentrum Berlin were involved in the study.