Nanocarbon catalysts with co‐active S−P−C sites enhance metal‐free direct oxidation of alcohols

SusMat Pub Date : 2024-07-15 DOI:10.1002/sus2.221

Juan Meng, Huidong Liu, Jianing Xu, Yu-Jiao Lou, Haixin Sun, Bo Jiang, Yongzhuang Liu, Hengfei Qin, Shuo Dou, Haipeng Yu

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Abstract

In this study, a sulfur–phosphorus co‐doped nanocarbon (SPC) catalyst was synthesized using a straightforward one‐step colloidal carbonization method and demonstrated high performance in the metal‐free direct oxidation of alcohols to aldehydes. This metal‐free SPC catalyst showed exceptional efficiency, achieving a conversion rate of 90% for benzyl alcohol and a selectivity of 94% toward benzaldehyde within only 1 h at 130°C. Moreover, it displays exceptional cycle stability and a high turnover frequency (17.1 × 10−3 mol g−1 h−1). Theoretical analysis suggested that the catalyst's superior performance is attributed to the presence of unsaturated edge defects and S−P− moieties, which increase the density of states at the Fermi level, lower the band gap energy, and promote electron localization. Additionally, the doping introduces cooperative co‐active S−P−C sites, facilitating a synergistic multisite catalytic effect that lowers the energy barriers. These findings represent a significant advancement in the field of metal‐free direct alcohol oxidation.

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具有共活 S-P-C 位点的纳米碳催化剂可增强醇的无金属直接氧化作用

本研究采用简单的一步胶体碳化法合成了硫磷共掺杂纳米碳（SPC）催化剂，该催化剂在将醇直接氧化成醛的无金属直接氧化过程中表现出高性能。这种无金属 SPC 催化剂表现出了极高的效率，在 130°C 温度下仅 1 小时内，苯甲醇的转化率就达到了 90%，对苯甲醛的选择性达到了 94%。此外，该催化剂还具有优异的循环稳定性和较高的周转频率（17.1 × 10-3 mol g-1 h-1）。理论分析表明，催化剂的优异性能归功于不饱和边缘缺陷和 S-P- 分子的存在，它们增加了费米级的态密度，降低了带隙能，促进了电子局域化。此外，掺杂还引入了协同作用的 S-P-C 位点，促进了多位点催化的协同效应，从而降低了能垒。这些发现代表了无金属直接醇氧化领域的重大进展。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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SusMat

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