Revolutionary visible-light-antenna ligand enhances samarium-catalyzed reactions

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Samarium (Sm), a rare earth metal, is significant to organic chemists due to the flexibility of its divalent compounds to efficiently perform single-electron transfer reductions. Samarium iodide (SmI2) is moderately stable and may operate under mild conditions at room temperature, making it highly useful for producing pharmaceuticals and biologically energetic materials. Nevertheless, most reactions require SmI2 in quantities equal to or greater than the stoichiometric amount and necessitate the usage of harmful chemicals, making the method resource-intensive and expensive to administer.

Several approaches have been studied to cut back the quantity of Sm reagents to catalytic amounts. Nevertheless, a lot of the currently available methods require harsh conditions and highly reactive reducing agents and still require significant amounts of Sm, typically 10-20% of the raw materials. Considering the high cost of Sm, there’s a big demand for an efficient catalyst system that uses minimal Sm under mild conditions.

In a recent breakthrough, a research team from Chiba University in Japan, led by Assistant Professor Takahito Kuribara from the Institute for Advanced Academic Research and the Graduate School of Pharmaceutical Sciences, developed an revolutionary method that significantly reduces the quantity of Sm. The team developed a 9,10-diphenyl anthracene (DPA)-substituted bidentate phosphine oxide ligand for coordination to trivalent samarium, enabling the usage of visible light to facilitate Sm-catalyzed reductive transformations. They call this ligand a visible-light antenna. Assistant Professor Kuribara explains, “Antenna ligands are known to assist in the excitation of lanthanoid metals like Sm. Previously, we reported a DPA-substituted secondary phosphine oxide ligand able to reduction-oxidation reactions under visible light. Inspired by this, we designed a brand new DPA-substituted bidentate phosphine oxide ligand that uses visible light to cut back the quantity of Sm to a catalytic level.”

The team included Ayahito Kaneki, Yu Matsuda, and Tetsuhiro Nemoto from the Graduate School of Pharmaceutical Sciences at Chiba University. Their study was made available online on July 20, 2024, and published in Volume 146, Issue 30 of the Journal of the American Chemical Society on July 31, 2024.

Through a series of experiments, the research team showed that using the Sm catalyst together with DPA-1 under blue-light irradiation produced high yields of as much as 98% for pinacol coupling reactions of aldehydes and ketones, that are commonly utilized in pharmaceuticals. Remarkably, these reactions could proceed with only 1-2 mol% of the Sm catalyst, a big reduction in comparison with the stoichiometric amounts typically required. Moreover, the reactions could proceed even with mild organic reducing agents like amines, in contrast to the highly reducing agents previously used.

The outcomes showed that the addition of a small amount of water improved yields, while excess water inhibited the response. Compared, DPA-2 and DPA, which have similar structures to DPA-1, yielded poor results.

To know why DPA-1 was so effective, the researchers studied the emission characteristics of the Sm catalyst and DPA-1 combination. They found that DPA-1, with its visible-light antenna, functions as a multifunctional ligand that coordinates with Sm, selectively absorbs blue light, and efficiently transfers electrons from the antenna to Sm.

The researchers successfully applied the Sm catalyst and DPA-1 combination to varied molecular transformation reactions, including carbon-carbon bond formation and carbon-oxygen and carbon-carbon bond cleavage, that are crucial for drug development. Furthermore, by utilizing visible light as an energy source, additionally they achieved molecular transformations that combined Sm-based reduction with photo-oxidation.

“Our recent visible-light antenna ligand reduced the quantity of Sm to 1-2 mol%, a big decrease in comparison with the stoichiometric amounts typically required, by utilizing low-energy visible light,” remarks Assistant Professor Kuribara. Adding further, he says, “Importantly, we were in a position to use trivalent Sm because the starting material, which is more stable and easier to handle as in comparison with divalent Sm.”

Overall, this study provides invaluable insights for further development and design of Sm-based catalysts, marking a big step forward in organic chemistry by enabling efficient Sm-catalyzed reductive transformations under mild conditions with minimal Sm loading.

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