From waste to value: The right electrolytes can enhance glycerol oxidation

The glycerol&rsquo;s hydroxyl groups are attracted to the Bi<sup>3+</sup> ions on the surface of the BiVO<sub>4</sub> photoanode. The electrolyte plays a decisive role in mediating these interactions.

The glycerol’s hydroxyl groups are attracted to the Bi3+ ions on the surface of the BiVO4 photoanode. The electrolyte plays a decisive role in mediating these interactions. © HZB

When biomass is converted into biodiesel, huge amounts of glycerol are produced as a by-product. So far, however, this by-product has been little utilised, even though it could be processed into more valuable chemicals through oxidation in photoelectrochemical reactors. The reason for this: low efficiency and selectivity. A team led by Dr Marco Favaro from the Institute for Solar Fuels at HZB has now investigated the influence of electrolytes on the efficiency of the glycerol oxidation reaction. The results can help to develop more efficient and environmentally friendly production processes.

 

In 2023, around 16 billion litres of biodiesel and HVO diesel were produced in the European Union*, based on maize, rapeseed, or partially on waste materials from agricultural production. A by-product of biodiesel production is glycerol, which can be used as a building block for the production of valuable chemicals such as dihydroxyacetone, formic acid, glyceraldehyde and glycolaldehyde via a glycerol oxidation reaction (GOR). Glycerol can be oxidised electrochemically in (photo)electrochemical (PEC) reactors, which are currently being developed in particular for the production of green hydrogen. However, this path in PEC-plants is still hardly exploited at present, even though it could significantly increase the economic efficiency of the PEC Power-to-X process, since the oxidation of glycerol requires a much lesser energy input than hydrogen production through water splitting, but at the same time produces more valuable chemicals.

Examining the influence of different electrolytes

Many studies have already investigated the role of photocatalysts in PEC electrolyzers, while the role of the electrolyte had not yet been systematically analysed. A team led by Dr Marco Favaro at the Institute for Solar Fuels has now unveiled the influence of electrolyte composition on the efficiency and stability of the glycerol oxidation.

They used a PEC cell with photoanodes made of nanoporous bismuth vanadate (BiVO4). They tested acidic electrolytes (pH = 2) with various cations and anions, including sodium nitrate (NaNO3), sodium perchlorate (NaClO4), sodium sulphate (Na2SO4), potassium sulphate (K2SO4) and potassium phosphate (KPi). "Our results showed that BiVO4 photoanodes perform best in NaNO3 and outperform the commonly used Na2SO4 in terms of photocurrent, stability, and production rates of high-quality glycerol oxidation reaction products," summarises Favaro.

Sodium nitrate performs best

The team also investigated the reasons for this difference in performance: their hypothesis is that the size of the ions, their different salting in/out capabilities (Hofmeister series), and their different pH buffering capacity play a role. "The composition of the electrolyte has a surprising clear effect on the glycerol oxidation efficiency, and we were able to observe this trend in both bismuth vanadate and polycrystalline platinum anodes," says PhD student Heejung Kong. This supports the assumption that these findings could generally apply to different materials and processes.

The choice of electrolyte is therefore of great importance for the efficiency and stability of glycerol oxidation. "Our research could help to convert biomass by-products into valuable chemicals more efficiently and to produce valuable chemicals from waste materials while minimising the impact on the environment," says Favaro.

Note: This work was supported by the European Innovation Council (EIC) via OHPERA project (grant agreement 101071010).

*Source:  https://de.statista.com/statistik/daten/studie/1179499/umfrage/produktion-von-biodiesel-und-erneuerbarem-diesel-eu/= 

arö

  • Copy link

You might also be interested in

  • Optical innovations for solar modules - which are the most promising?
    Science Highlight
    28.03.2025
    Optical innovations for solar modules - which are the most promising?
    In 2023, photovoltaic systems generated more than 5% of the world’s electrical energy and the installed capacity doubles every two to three years. Optical technologies can further increase the efficiency of solar modules and open up new applications, such as coloured solar modules for facades. Now, 27 experts provide a comprehensive overview of the state of research and assess the most promising innovations. The report, which is also of interest to stakeholders in funding and science management, was coordinated by HZB scientists Prof. Christiane Becker and Dr. Klaus Jäger.
  • Catalysis research with the X-ray microscope at BESSY II
    Science Highlight
    27.03.2025
    Catalysis research with the X-ray microscope at BESSY II
    Contrary to what we learned at school, some catalysts do change during the reaction: for example, certain electrocatalysts can change their structure and composition during the reaction when an electric field is applied. The X-ray microscope TXM at BESSY II in Berlin is a unique tool for studying such changes in detail. The results help to develop innovative catalysts for a wide range of applications. One example was recently published in Nature Materials. It involved the synthesis of ammonia from waste nitrates.
  • BESSY II: Magnetic ‘microflowers’ enhance magnetic fields locally
    Science Highlight
    25.03.2025
    BESSY II: Magnetic ‘microflowers’ enhance magnetic fields locally
    A flower-shaped structure only a few micrometres in size made of a nickel-iron alloy can concentrate and locally enhance magnetic fields. The size of the effect can be controlled by varying the geometry and number of 'petals'. This magnetic metamaterial developed by Dr Anna Palau's group at the Institut de Ciencia de Materials de Barcelona (ICMAB) in collaboration with her partners of the CHIST-ERA MetaMagIC project, has now been studied at BESSY II in collaboration with Dr Sergio Valencia. Such a device can be used to increase the sensitivity of magnetic sensors, to reduce the energy required for creating local magnetic fields, but also, at the PEEM experimental station, to study samples under much higher magnetic fields than currently possible.