Enhanced Biomass Valorisation by Engineering of Polyoxometalate Catalysts

ERC (European Research Council)HORIZON-ERCID: 101086573
EC Contribution
€19,966
Consortium Size
1 orgs
Start Year
2023
Summary

This project builds on a recent and ground-breaking discovery of the PI in the field of homogeneously catalysed, selective biomass valorisation. Materials technologies that promise improved catalytic performance are of utmost interest for a more sustainable chemical industry. Manipulating molecular catalysts like polyoxometalates (POM) in solution by tuning the solvent properties and gas atmospheres introduces a new paradigm in homogeneous-catalysed biomass valorisation technologies.It has been found that by using methanol as a (co)solvent, POM catalysts can completely suppress undesired total oxidation to CO2 under oxidative conditions. This drastically enhances the carbon efficiency from biomass to close to 100% yield. Remarkably, this manipulating effect could be explained with the formation of a new vanadyl-methanolate-complex in methanol-aqueous solutions having a methanol content of at least 10%.The proposed BioValCat project aims for developing this potentially disruptive technology towards an industrial viable biomass valorisation process by laying the foundations for a scalable, safe and economic process for the oxidation of biomass to valuable carboxylic acid esters. The project is structured according to the key challenges that have to be mastered in order to achieve this ambitious goal: a) Investigations to identify the nature of the POM-solvent interactions; b) Understanding and revealing the key organic mechanisms in solution; c) Development of novel POM catalysts specifically optimised to perform in aqueous-alcoholic solvent mixtures; d) Extension of the substrate and product scope to industrially viable biomass feedstock; e) Process development, with special emphasis on safety aspects, process intensification as well as product isolation and catalyst recovery.With the proposed project the PI aims for paving the scientific route to novel, low-cost biomass utilisation technologies with great promise for decentralised valorisation of biogenic waste.

Consortium (1)

Project Results (4)

Source: CORDIS, the EU research results database.

Publications (4)
Comparing the Polyoxometalate-Catalyzed Oxidation of C5-Containing Biomass to Formic Acid in a Taylor-Flow Microreactor and a Stirred-Tank Reactor
ACS Sustainable Chemistry & Engineering· 2025DOI
Jan-Dominik H. Krueger, Lukas Popp, Markus Schörner, Hans Lorenz Grau, Patrick Schühle, Jakob Albert
In‐Situ Investigations of Polyoxometalate‐Catalysed Biomass Oxidation to Formic Acid by Using Multinuclear High Resolution Flow NMR Spectroscopy
ChemCatChem· 2025DOI
Jan‐Dominik H. Krueger, Maximilian J. Poller, Catherine Lyall, John Lowe, Ulrich Hintermair, Jakob Albert
Influence of Reactive Additives on the Polyoxometalate‐Catalyzed Oxidation of Xylose to Formic Acid
ChemCatChem· 2025DOI
Jan‐Dominik H. Krueger, Dhanushiyaa. Sivarajah, Maximilian J. Poller, David. Robinson, Jakob. Albert
Conversion of Sugars to Lactic Acid using Homogeneous Niobium‐Substituted Polyoxometalate Catalysts
Chemistry – A European Journal· 2024DOI
Anne Wesner, Jan‐Christian Raabe, Maximilian J. Poller, Sebastian Meier, Anders Riisager, Jakob Albert