Hybrid cascade process selectively converts CO鈧� into methanol

January 13, 2025

Hybrid cascade process selectively converts CO鈧� into methanol

Inorganic and biocatalysts work together to reduce CO-2 — Graphical Abstract. Towards the development of technologies for the conversion of excess atmospheric CO₂, a hybrid electrocatalytic/bioelectrocatalytic system combining an inorganic catalyst with a bienzymatic cascade for CO₂ electroreduction to methanol is presented. The Ag-Bi₂O₃ electrocatalyst enables the selective conversion of CO₂ to formate. The generated formate is subsequently converted in a two-step process catalyzed by the two NADH-dependent enzymes, formaldehyde dehydrogenase and alcohol dehydrogenase, via formaldehyde to methanol. NADH regeneration is ensured by diaphorase wired to the electrode by a redox polymer. Credit: *Angewandte Chemie International Edition* (2024). DOI: 10.1002/anie.202422882

In a hybrid cascade, climate-damaging CO₂ is turned back into valuable methanol. An international research team has shown how this works.

In order to recover valuable substances from CO₂, it must be reduced in many individual steps. If electrocatalysis is used for this, many potentially different potential molecules are formed, which cannot necessarily be used. Biocatalysts, on the other hand, are selective and only produce one product鈥攂ut they are also very sensitive.

An international research team led by Professor Wolfgang Schuhmann from the Center for Electrochemistry at Ruhr-Universit盲t Bochum, Germany, and Dr. Felipe Conzuelo from the Universidade Nova de Lisboa, Portugal, has developed a hybrid catalysis cascade that makes use of the advantages of both processes. The researchers in the journal Angewandte Chemie International Edition from December 23, 2024.

Advantages and disadvantages of electrocatalysis and biocatalysis

Methanol is one of the substances that we would like to obtain from climate-damaging CO₂. It is often used as a synthesis raw material in the chemical industry.

"Many reduction steps are required to produce methanol, as carbon dioxide is the most highly oxidized form of carbon," explains Schuhmann.

Electrocatalysis is able to initiate these steps. However, while it is still selective in the first step, the reaction path then branches out and up to 16 different products are formed, not necessarily methanol. The situation is different with biocatalysts: these natural enzymes catalyze just one reaction and therefore only yield one product. However, they are complicated to handle, very sensitive or require cofactors for the reaction.

Combining both processes

In order to combine the advantages of both processes, the team led by first authors Panpan Wang and Xin Wang married electrocatalysis and biocatalysis. While the first reaction step from CO₂ to formate is electrocatalytic, the second and third steps are catalyzed by formaldehyde dehydrogenase and alcohol dehydrogenase.

These enzymes require NAD (nicotinamide adenine dinucleotide) as a cofactor, which is consumed by the catalytic reaction and must be regenerated. This regeneration is achieved by a third enzyme. Finally, the valuable substance methanol is produced.

"The work proves that such hybrid cascades are in principle feasible and make complex, multi-step reactions selectively possible," summarizes Schuhmann.

More information: Panpan Wang et al, Hybrid Enzyme鈥怑lectrocatalyst Cascade Modified Gas鈥怐iffusion Electrodes for Methanol Formation from Carbon Dioxide, Angewandte Chemie International Edition (2024).

Journal information: Angewandte Chemie International Edition

Provided by Ruhr-Universitaet-Bochum

Citation: Hybrid cascade process selectively converts CO鈧� into methanol (2025, January 13) retrieved 10 September 2025 from /news/2025-01-hybrid-cascade-methanol.html

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