Microenvironment and electronic state modulation of Pd nanoparticles within MOFs for enhancing low-temperature activity towards DCPD hydrogenation

doi:10.1016/S1872-2067(24)60095-1

Abstract

Abstract:

Precise control of the local environment and electronic state of the guest is an important method of controlling catalytic activity and reaction pathways. In this paper, guest Pd NPs were introduced into a series of host UiO-67 MOFs with different functional ligands and metal nodes, the microenvironment and local electronic structure of Pd is modulated by introducing bipyridine groups and changing metal nodes (Ce₆O₆ or Zr₆O₆). The bipyridine groups not only promoted the dispersion Pd NPs, but also facilitated electron transfer between Pd and UiO-67 MOFs through the formation of Pd-N bridges. Compared with Zr₆ clusters, the tunability and orbital hybridisation of the 4f electronic structure in the Ce₆ clusters modulate the electronic structure of Pd through the construction of the Ce-O-Pd interfaces. The optimal catalyst Pd/UiO-67(Ce)-bpy presented excellent low-temperature activity towards dicyclopentadiene hydrogenation with a conversion of > 99% and a selectivity of > 99% (50 °C, 10 bar). The results show that the synergy of Ce-O-Pd and Pd-N promotes the formation of active Pd^δ⁺, which not only enhances the adsorption of H₂ and electron-rich C=C bonds, but also contributes to the reduction of proton migration distance and improves proton utilization efficiency. These results provide valuable insights for investigating the regulatory role of the host MOFs, the nature of host-guest interactions, and their correlation with catalytic performance.

Key words: Interface regulation, Pd^δ⁺, Microenvironment, Electronic state, Hydrogenation

Zhiyuan Liu, Changan Wang, Ping Yang, Wei Wang, Hongyi Gao, Guoqing An, Siqi Liu, Juan Chen, Tingting Guo, Xinmeng Xu, Ge Wang. Microenvironment and electronic state modulation of Pd nanoparticles within MOFs for enhancing low-temperature activity towards DCPD hydrogenation[J]. Chinese Journal of Catalysis, 2024, 64: 112-122.

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URL: https://www.cjcatal.com/EN/10.1016/S1872-2067(24)60095-1

https://www.cjcatal.com/EN/Y2024/V64/I9/112

Figures/Tables 6

Scheme 1. (a) Illustration of the fabrication process of UiO-67(Ce)-bpy, UiO-67(Ce), UiO-67(Zr)-bpy, UiO-67(Zr), Pd/UiO-67(Ce)-bpy, Pd/UiO-67(Ce), Pd/UiO-67(Zr)-bpy, and Pd/UiO-67(Zr). (b) Illustration of DCPD hydrogenation.

Fig. 1. TEM image of Pd/UiO-67(Ce)-bpy (a), Pd/UiO-67(Ce) (b), Pd/UiO-67(Zr)-bpy (c), and Pd/UiO-67(Zr) (d), and EDX of Pd/UiO-67(Ce)-bpy (e?i).

Fig. 2. The DCPD hydrogenation of Pd/UiO-67(Ce)-bpy, Pd/UiO-67(Ce), Pd/UiO-67(Zr)-bpy, and Pd/UiO-67(Zr) (a), at different temperatures (b), at different pressures (c), and at different times (d). DCPD hydrogenation (e) and cycling stability experiments (f) of Pd/UiO-67(Ce)-bpy.

Fig. 3. (a) The high-resolution Zr 3d spectra of Pd/UiO-67(Zr)-bpy and Pd/UiO-67(Zr). (b) N 1s spectra of Pd/UiO-67(Zr)-bpy and Pd/UiO-67(Ce)-bpy. Pd 3d (c) and Ce 3d (d) XPS spectra of Pd/UiO-67(Ce)-bpy and Pd/UiO-67(Ce).

Fig. 4. CO-DRIFTS (a), the NH3-TPD curve (b), the Raman spectra (c), partial enlargement (d) of Pd/UiO-67(Ce)-bpy and Pd/UiO-67(Ce). (e) The H2-TPR curve of Pd/UiO-67(Ce)-bpy, Pd/UiO-67(Ce), Pd/UiO-67(Zr)-bpy, and Pd/UiO-67(Zr). (f) The TG-DSC curve of Pd/UiO-67(Ce)-bpy and Pd/UiO-67(Ce).

Fig. 5. Proposed mechanism for DCPD hydrogenation on Pd/UiO-67(Ce)-bpy.

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