How photoelectrodes change in contact with water

Water adsorption and dissociation on the bismuth vanadate surface causes localization of excess electrons into small polaron states at vanadium sites, indicated by the yellow and blue clouds.

Water adsorption and dissociation on the bismuth vanadate surface causes localization of excess electrons into small polaron states at vanadium sites, indicated by the yellow and blue clouds. © HZB / J. Am. Chem. Soc. 2022

2D map of the valence band states (x-axis in eV) in Mo-doped BiVO<sub>4</sub> as a function of photon energy (y-axis). The presence of small polarons can be deducted from the spot at approx. 2 eV.

2D map of the valence band states (x-axis in eV) in Mo-doped BiVO4 as a function of photon energy (y-axis). The presence of small polarons can be deducted from the spot at approx. 2 eV. © HZB / J. Am. Chem. Soc. 2022

Photoelectrodes based on BiVO4 are considered top candidates for solar hydrogen production. But what exactly happens when they come into contact with water molecules? A study in the Journal of the American Chemical Society has now partially answered this crucial question:  Excess electrons from dopants or defects aid the dissociation of water which in turn stabilizes so-called polarons at the surface. This is shown by data from experiments conducted at the Advanced Light Source at Lawrence Berkeley National Laboratory. These insights might foster a knowledge-based design of better photoanodes for green hydrogen production.

 

Every green leaf is able to convert solar energy into chemical energy, storing it in chemical compounds. However, an important sub-process of photosynthesis can already be technically imitated - solar hydrogen production: Sunlight generates a current in a so-called photoelectrode that can be used to split water molecules. This produces hydrogen, a versatile fuel that stores solar energy in chemical form and can release it when needed.

Photoelectrodes with many talents

At the HZB Institute for Solar Fuels, many teams are working on this vision. The focus of their research is on producing efficient photoelectrodes. These are semiconductors that remain stable in aqueous solutions and are highly active: Not only can they convert sunlight into electrical current, but they may also act as catalysts to accelerate the splitting of water. Among the best candidates for inexpensive and efficient photoelectrodes is bismuth vanadate (BiVO4).

What happens when in water?

"Basically, we know that just by immersing bismuth vanadate in the aqueous solution the chemical composition of the surface changes," says Dr. David Starr of the HZB Institute for Solar Fuels. And his colleague Dr. Marco Favaro adds: "Although there are a great many studies on BiVO4, it has not been clear until now exactly what implications this has on the surface electronic properties once they come into contact with the water molecules." In this work, they have now investigated this question.  

Doped BiVO4 under water vapor

They studied single crystals of BiVO4 doped with molybdenum under water vapor with resonant ambient pressure photoemission spectroscopy at the Advanced Light Source at Lawrence Berkeley National Laboratory. A team led by Giulia Galli at the University of Chicago then performed density functional theory calculations to help interpret the data and to untangle the contributions of individual elements and electron orbitals to the electronic states. 

Polarons on the surface detected

In situ resonant photoemission has allowed us to understand how the electronic properties of our BiVO4 crystals changed upon water adsorption”, Favaro says. The combination of measurements and calculations showed that due to excess charge, generated by either doping or defects on certain surfaces of the crystal, so-called polarons may form: negatively charged localized states, where water molecules can easily attach and then dissociate. The hydroxyl groups formed via water dissociation help to stabilize further polaron formation.  "The excess electrons are localized as polarons at VO4 units on the surface," Starr summarizes the results.

Knowledge based optimization

"What we can't yet assess for sure is what role the polarons play in charge transfer. Whether they promote it and thus increase efficiency or, on the contrary, are an obstacle, we still need to figure that out," Starr admits. The results provide valuable insights into processes that modify the surface chemical composition and electronic structure and might foster the knowledge-based design of better photoanodes for green hydrogen production.

arö

  • Copy link

You might also be interested in

  • 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.
  • Innovative Catalyst Platform Advances Understanding of Working Catalysts
    Science Highlight
    11.12.2024
    Innovative Catalyst Platform Advances Understanding of Working Catalysts
    A novel catalyst platform, known as Laterally Condensed Catalysts (LCC), has been developed to enable design and analysis of the functional interface connecting the active mass to its support. This interface not only influences the chemical properties of the reactive interface but also controls its stability and hence the sustainability of the catalytic materials. The development was significantly supported by the use of operando spectroscopy at the BESSY II synchrotron, which made it possible to observe and understand the dynamic processes and structures under reaction conditions.
  • Catalyst Activation and Degradation in Hydrous Iridium Oxides
    Science Highlight
    10.12.2024
    Catalyst Activation and Degradation in Hydrous Iridium Oxides
    The development of efficient catalysts for the Oxygen Evolution Reaction (OER) is crucial for advancing Proton Exchange Membrane (PEM) water electrolysis, with iridium-based OER catalysts showing promise despite the challenges related to their dissolution. Collaborative research by the Helmholtz-Zentrum Berlin für Materialien und Energie GmbH and the Fritz-Haber-Institut has provided insights into the mechanisms of OER performance and iridium dissolution for amorphous hydrous iridium oxides, advancing the understanding of this critical process.