Wu Jiale, Wang Liguo, Xu Shuang, Cao Yan, Han Ziqiang, Li Huiquan
National Engineering Research Center of Green Recycling for Strategic Metal Resources, Institute of Process Engineering, Chinese Academy of Sciences Beijing 100190 China
Sino-Danish College, University of Chinese Academy of Sciences Beijing 100049 China.
RSC Adv. 2023 Jan 11;13(3):2024-2035. doi: 10.1039/d2ra07612h. eCollection 2023 Jan 6.
Developing efficient and green catalytic systems is highly desired in the syntheses of alicyclic amines hydrogenation of nitroaromatics. Herein, we developed Ru-Pd dual active site catalysts in which Ru and Pd species were anchored and highly dispersed on air-exfoliated carbon nitride (Ru-Pd/CN-air). As-prepared catalysts were employed in the hydrogenation of nitrobenzene (NB) to cyclohexylamine (CHA). Compared with single Ru or Pd based catalysts, Ru-Pd dual active site catalysts obtained a higher CHA production rate of 26.7 mol CHA mol Ru·Pd h at 80 °C and 3 MPa H. The activation energy for the hydrogenation of the nitro group and benzene ring was calculated as 26.26 kJ mol and 66.30 kJ mol, respectively. Intrinsic kinetic studies demonstrated that Pd was the dominant metal for hydrogenation of nitro group, while Ru was dominant for benzene ring. Thereinto, the corresponding non-dominant metals enhanced activation and dissociation of H, thereby improving catalytic activity significantly. This excellent performance of Ru-Pd catalysts could be attributed to highly dispersed Ru-N and Pd-N at a nanoscale distance, which was conducive to metal-assisted hydrogenation. Stability investigation showed that the performance of Ru-Pd catalysts could be essentially maintained at a high level. Additionally, the substrate scope could be successfully extended to hydrogenation of other nitroaromatics with different substituents.
在脂环胺的合成以及硝基芳烃的氢化反应中,开发高效且绿色的催化体系是非常必要的。在此,我们开发了Ru-Pd双活性位点催化剂,其中Ru和Pd物种被锚定并高度分散在空气剥离的氮化碳上(Ru-Pd/CN-air)。将制备好的催化剂用于硝基苯(NB)加氢制环己胺(CHA)的反应中。与单一的Ru或Pd基催化剂相比,Ru-Pd双活性位点催化剂在80℃和3MPa氢气条件下获得了更高的CHA产率,为26.7 mol CHA mol Ru·Pd h。计算得出硝基和苯环氢化的活化能分别为26.26 kJ mol和66.30 kJ mol。本征动力学研究表明,Pd是硝基氢化的主要金属,而Ru是苯环氢化的主要金属。其中,相应的非主要金属增强了H的活化和解离,从而显著提高了催化活性。Ru-Pd催化剂的这种优异性能可归因于纳米级距离下高度分散的Ru-N和Pd-N,这有利于金属辅助氢化。稳定性研究表明,Ru-Pd催化剂的性能可基本保持在高水平。此外,底物范围可以成功扩展到其他具有不同取代基的硝基芳烃的氢化反应。
