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Chemists turn metal catalysis on its head for a sustainable future

Researchers take a nonintuitive approach to metal catalysis for selective conversion of biomass into high-value chemical products under mild conditions

Date:
June 27, 2017
Source:
Nagoya University
Summary:
A research team used high-valent transition metal catalysts for an unconventional hydrogenation of carboxylic acid groups, common to biomass feedstocks. The high-valent catalysts showed good selectivity under mild conditions.
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The uncertain future of oil feedstocks and environmental pressure are forcing the chemical industry to adapt and find new renewable sources to sustain its activities. Biomass from sources including wood, agricultural waste, and even human garbage, represents a widely available renewable feedstock that has yet to be fully tapped. The problem is that most biomass is a mess of different chemicals, which are difficult to separate and use in high-value products such as plastics and pharmaceuticals.

Carboxylic acids are one of the most common chemical groups in biomass, and their chemical reactions are particularly difficult to control in these mixtures. Currently used "catalytic hydrogenation" with metal catalysts can transform the acids into more useful alcohol groups, but also adds to the complexity of the biomass because of other side reactions and catalyst decomposition.

Recognizing the need for more selective transformations of carboxylic acid groups, a team at Nagoya University explored a different chemical approach to the catalysis of biomass.

"Traditionally, low-valent transition metal complexes are used for hydrogenation of carboxylic acids. But we found better selectivity under milder conditions using a high-valent complex, which also attacked carbon-hydrogen bonds next to the carboxylic acid," says lead author Masayuki Naruto.

Hydrogenation is essentially a reduction, during which the metal catalyzes transfer of electrons to the carboxylic acid. Low-valence metals are electron rich, which makes them the obvious choice for hydrogenation of carboxylic acids. However, the team showed that high valence metals could also react with the carboxylic acids by a different pathway, which offered much better control over the reactivity.

"The idea that high-valent transition metals are effective for this kind of reaction might go against traditional wisdom, but we have shown the potential of this approach for making high-value chemical products from biomass," says group leader Susumu Saito. "Although, the rhenium metal catalyst we used here is rather expensive, we are now looking at recycling the catalyst and alternative tungsten and molybdenum catalysts, which should make this a truly economically viable approach for getting useful products from biomass in the future."


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Materials provided by Nagoya University. Note: Content may be edited for style and length.


Journal Reference:

  1. Masayuki Naruto, Santosh Agrawal, Katsuaki Toda, Susumu Saito. Catalytic transformation of functionalized carboxylic acids using multifunctional rhenium complexes. Scientific Reports, 2017; 7 (1) DOI: 10.1038/s41598-017-03436-y

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Nagoya University. "Chemists turn metal catalysis on its head for a sustainable future." ScienceDaily. ScienceDaily, 27 June 2017. <www.sciencedaily.com/releases/2017/06/170627134340.htm>.
Nagoya University. (2017, June 27). Chemists turn metal catalysis on its head for a sustainable future. ScienceDaily. Retrieved December 26, 2024 from www.sciencedaily.com/releases/2017/06/170627134340.htm
Nagoya University. "Chemists turn metal catalysis on its head for a sustainable future." ScienceDaily. www.sciencedaily.com/releases/2017/06/170627134340.htm (accessed December 26, 2024).

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