Producing carboxylic acids employing an environmentally friendly technique
Researchers at Mainz University and Evonik have developed an innovative method to cleave and oxidize double- and triple-bonds in hydrocarbons
Polyamides are present in many different products, such as ropes for mountaineering, parachutes of nylon, and materials for 3D printing. Dicarboxylic acids are used as chemical building blocks for these polyamides. However, their production has been challenging to date because current methods of generating dicarboxylic acids from saturated or unsaturated hydrocarbons frequently involve multiple steps as well as the use of heavy metals and strong acids, while the related energy consumption and costs are extensive. Furthermore, the process often results in the release of nitrogen oxides (NOx), which are among the most problematic greenhouse gases as far as the climate is concerned. Researchers at Johannes Gutenberg University Mainz (JGU) and Evonik have recently developed an environmentally friendly way to produce (di)carboxylic acids. They report on this in a paper recently published in Nature Communications.
Electrochemistry provides new opportunities
"Our technique is the first-ever process to make the building blocks for polyamides from petrochemical compounds and even unsaturated fatty acids using a fairly sparing approach," said Professor Siegfried Waldvogel, speaker of the SusInnoScience – Sustainable Chemistry as the Key to Innovation in Resource-efficient Science in the Anthropocene – research focus at Mainz University. The new technique involves an electrochemical method in which hydrocarbons with double or triple bonds are transferred to an electrolysis cell filled with a solvent. Oxygen is then added, whereby the greater the oxygen concentration, the more efficient the process.
"What is really fascinating about our process is that the electrochemical intervention is needed at both the anode and the cathode," explained Waldvogel. While oxidative radicals are created at the anode, the oxygen at the opposite electrode is reduced to superoxide anions. The radicals and the superoxide anions come together in the solution and react to form the desired product, carboxylic acid. The researchers have repeated the process successfully in both standard and flow electrolytic cells.
Process requires only oxygen, electricity, and hydrocarbon compounds
This new technique has many advantages: Heavy metals and strong acids are no longer necessary while no nitrogen oxides are generated. The only starting materials needed are oxygen, electricity, and hydrocarbons with double bonds. Because no byproducts are created and the solvent can be recovered and recycled, the process is very cost-effective. "This is an innovative and less detrimental process for producing carboxylic acids, thus providing a valuable contribution to those manufacturers who wish to replace the climate-damaging processes with a green approach," concluded Waldvogel. The research team is currently working on a scale-up of the lab process to make it practicable for commercial use.
Image:
https://download.uni-mainz.de/presse/personal_09_waldvogel.jpg
Professor Dr. Siegfried Waldvogel, spokesperson of the SusInnoScience – Sustainable Chemistry as the Key to Innovation in Resource-efficient Science in the Anthropocene – research focus at Mainz University
photo/©: Eric Lichtenscheidt
Related links:
https://susinnoscience.uni-mainz.de/ – SusInnoScience Top-level Research Area at JGU
Read more:
• https://press.uni-mainz.de/sustainable-process-for-the-production-of-vanillin-from-lignin-makes-further-progress/ – press release "Sustainable process for the production of vanillin from lignin makes further progress" (2 Mar. 2023)
• https://press.uni-mainz.de/sustainable-recycling-using-electrochemistry-carl-zeiss-foundation-supports-new-research-project/ – press release "Sustainable recycling using electrochemistry: Carl Zeiss Foundation supports new research project" (3 Nov. 2022)
• https://press.uni-mainz.de/clusters4future-approval-for-johannes-gutenberg-university-mainz-to-translate-electro-organic-synthesis/ – press release "Clusters4Future approval for Johannes Gutenberg University Mainz to translate electro-organic synthesis" (25 July 2022)
Wissenschaftlicher Ansprechpartner:
Professor Dr. Siegfried Waldvogel
Department of Chemistry
Johannes Gutenberg University Mainz
55099 Mainz, GERMANY
phone: +49 6131 39-26069
e-mail: waldvogel@uni-mainz.de
https://www.aksw.uni-mainz.de/
Originalpublikation:
J. Nikl et al., Electrochemical oxo-functionalization of cyclic alkanes and alkenes using nitrate and oxygen, Nature Communications 14: 4565, 28 July 2023,
DOI: 10.1038/s41467-023-40259-0
https://doi.org/10.1038/s41467-023-40259-0