本课题组研究生祝宏亮以第一作者在《Sustainable Energy & Fuels》上发表论文《Synergistic effffect of PtNi alloy loading on TiB2 to construct SMSI catalysing formic acid dehydrogenation》。
论文摘要:
Low-cost and highly active catalysts are attractive for catalysing formic acid (FA) dehydrogenation at room temperature. The PtNi alloy nanoparticles with the characteristic of lattice contraction and synergy effffects were loaded on two-dimensional TiB2 by incipient-wetness impregnation. Compared to Pt/TiB2, the substitution of Ni reduces the amount of noble metal required, with the added advantage of signifificantly improving the catalyst activity by sixteen times. By investigating the various PtNi ratios, the Pt3Ni8/TiB2 (total metal loading = 2.0 wt%) catalyst was found to provide a low activation energy of 27.7 kJ mol−1 in 10.0 M FA aqueous solution at room temperature. This is the fifirst example of using the alloy supported on TiB2 to achieve strong metal–support interaction (SMSI) to catalyse formic acid dehydrogenation at ambient temperature. XPS and TEM characterisation studies show that higher temperatures induced TiB2 to encapsulate the PtNi NPs, with the TiB2 surfaces serving as the active site for catalysing FA dehydrogenation. The catalytic activity of the obtained Pt3Ni8/TiB2 catalyst for the dehydrogenation of FA was much higher than those of its monometallic counterparts (Pt/TiB2 and Ni/TiB2) prepared by the same method, while demonstrating higher stability against agglomeration and CO poisoning. The excellent catalytic activity and stability of Pt3Ni8/TiB2 were mainly attributed to the presence of the SMSI effffect of the catalyst. Additionally, the lattice distortion and local interactions within the ferromagnetic clusters of Pt3Ni8 alloy NPs created a synergistic effffect, which resulted in an enhanced SMSI effffect throughout the catalyst. This study introduces a new concept that magnetic Ni metal partially replacing noble metals can improve thermal stability and catalytic performance, while enabling facile catalyst recovery. Moreover, this research demonstrates that the controlled synthesis and rational design of 2D reticular crystal structure TiB2-supported alloy NPs may provide new opportunities to enhance the catalytic activity and improve the SMSI effffect of noble metal-based nanostructures.