AI Article Synopsis
- The article details a new method for recycling a hydroformylation catalyst using selective adsorption to custom-designed supports after the reaction.
- The catalyst separation relies on non-covalent interactions between a ligand and the support, allowing the active catalyst to be released for reuse by changing the solvent.
- A specific rhodium pre-catalyst shows high stability and efficiency, achieving a turnover number of 170,000, with successful recycling demonstrated through multiple runs using end-capped silica-alumina supports.
Article Abstract
This article describes a new strategy for the recycling of a homogeneous hydroformylation catalyst, by selective adsorption of the catalyst to tailor-made supports after a batchwise reaction. The separation of the catalyst from the product mixture is based on selective non-covalent supramolecular interactions between a ligand and the support. Changing the solvent releases the active catalyst back into the reactor and allows a subsequent batch reaction with the recycled active catalyst. For this purpose, the bidentate NixantPhos ligand has been equipped with a pyridine group. The corresponding rhodium pre-catalyst [Rh(Nix-py)(acac)] (acac = acetylacetonate) forms a very selective, active and highly stable catalyst, and able to reach a turnover number (TON) of 170 000 in a single run (reaction performed in nearly neat 1-octene, S/C ratio of 200 000, at 140 °C, 20 bars syngas pressure). Various commercially available supports have been explored in binding studies and recycling experiments. The end-capped silica-alumina performs the best so far with respect to ligand-adsorbing properties for the current purpose. Although this system has not been fully optimized, four recycling runs could be performed successfully.
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| http://dx.doi.org/10.1039/c2dt32047a | DOI Listing |
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