アイテム詳細

要旨

Metal phosphides have been hailed as potential replacements for scarce noble metal catalysts in many aspects of the hydrogen economy from hydrogen evolution to selective hydrogenation reactions. But the need for dangerous and costly phosphorus precursors, limited support dispersion, and low stability of the metal phosphide surface toward oxidation substantially lower the appeal and performance of metal phosphides in catalysis. We show here that a 1-step procedure that relies on safe and cheap precursors can furnish an air-stable Ni₂P/Al₂O₃ catalyst containing 3.2 nm nanoparticles. Ni₂P/Al₂O₃ 1-step is kinetically competitive with the palladium-based Lindlar catalyst in selective hydrogenation catalysis, and a loading corresponding to 4 ppm Ni was sufficient to convert 0.1 mol alkyne. The 1-step synthetic procedure alters the surface ligand speciation of Ni₂P/Al₂O₃, which protects the nanoparticle surface from oxidation, and ensures that 85% of the initial catalytic activity was retained after the catalyst was stored under air for 1.5 years. Preparation of Ni₂P on a variety of supports (silica, TiO₂, SBA-15, ZrO₂, C and HAP) as well as Co₂P/Al₂O₃, Co₂P/TiO₂ and bimetallic NiCoP/TiO₂ demonstrates the generality with which supported metal phosphides can be accessed in a safe and straightforward fashion with small sizes and high dispersion.