Selective hydrodeoxygenation of oxygenated aromatic molecules using a molecular palladium catalyst covalently bound to a solid SiO2 support†

Jake G. Tillou, Joseph J. Kuchta, Nathan Thornburg, Santosh K. Balijepalli and Aaron K. Vannucci
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Abstract

The selective hydrodeoxygenation of lignin derived aromatics represents an important step towards the valorization of biomass. With this goal in mind, we synthesized a hybrid molecular/heterogeneous catalyst comprised of a (2,6-bis(1-methylbenzimidazolyl)pyridine-4′-aminopropyltrisiloxane)palladium(II) molecular catalyst covalently bound to a solid silica support through the siloxane functional group. A series of model complexes containing C–O bonds typically found in lignin biomass were explored and varying degrees of C–O bond hydrogenation were achieved. The stable covalent binding of the catalyst to the support was attributed to the observed long catalyst lifetimes which led to over 6000 catalytic turnovers without catalyst deactivation. Spectroscopic characterization of the catalyst pre- and post-catalytic reactions shows the catalyst maintains molecular integrity under the reaction conditions examined. The catalyst also exhibited complete selectivity for hydrodeoxygenation over ring hydrogenation of oxygenated aromatic molecules.

Abstract Image

Abstract Image

使用与固体二氧化硅载体共价结合的分子钯催化剂对含氧芳香分子进行选择性氢脱氧反应
木质素衍生芳烃的选择性加氢脱氧是实现生物质增值的重要一步。带着这一目标,我们合成了一种混合分子/异质催化剂,由通过硅氧烷官能团与固体二氧化硅载体共价结合的(2,6-双(1-甲基苯并咪唑基)吡啶-4′-氨基丙基三硅氧烷)钯(II)分子催化剂组成。研究人员探索了一系列含有木质素生物质中常见的 C-O 键的模型复合物,并实现了不同程度的 C-O 键氢化。由于催化剂与载体的共价结合稳定,因此观察到催化剂的寿命较长,超过 6000 次催化翻转也未出现催化剂失活现象。催化剂催化前和催化后反应的光谱表征表明,催化剂在所考察的反应条件下保持了分子的完整性。此外,该催化剂在含氧芳香分子的氢脱氧反应和环氢化反应中具有完全的选择性。
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