A Robust and Efficient Propane Dehydrogenation Catalyst from Unexpectedly Segregated Pt 2 Mn Nanoparticles.

The increasing demand for short chain olefins like propene for plastics production and the availability of shale gas make the development of highly performing propane dehydrogenation (PDH) catalysts, robust toward industrially applied harsh regeneration conditions, a highly important field of research. A combination of surface organometallic chemistry and thermolytic molecular precursor approach was used to prepare a nanometric, bimetallic Pt-Mn material (3 wt % Pt, 1.3 wt % Mn) supported on silica via consecutive grafting of a Mn and Pt precursor on surface OH groups present on the support surface, followed by a treatment under a H 2 flow at high temperature. The material exhibits a 70% fraction of the overall Mn as Mn II single sites on the support surface; the remaining Mn is incorporated in segregated Pt 2 Mn nanoparticles. The material shows great performance in PDH reaction with a low deactivation rate. In particular, it shows outstanding robustness during repeated regeneration cycles, with conversion and selectivity stabilizing at ca. 37 and 98%, respectively. Notably, a material with a lower Pt loading of only 0.05 wt % shows an outstanding catalytic performance─initial productivity of 4523 g C 3 H 6 /g Pt h and an extremely low k d of 0.003 h -1 under a partial pressure of H 2 , which are among the highest reported productivities. A combined in situ X-ray absorption spectroscopy, scanning transmission electron microscopy, electron paramagnetic resonance, and metadynamics at the density functional theory level study could show that the strong interaction between the Mn II -decorated support and the unexpectedly segregated Pt 2 Mn particles is most likely responsible for the outstanding performance of the investigated materials.