Engineering high-performance palladium core magnesium oxide porous shell nanocatalysts via heterogeneous gas-phase synthesis

The invention claimed is: 1. A method for manufacturing Pd core-MgO shell nanoparticles, the method comprising: forming a vapor including both of a super-saturated vapor of Mg and a super-saturated vapor of Pd by sputtering using an Mg target and a Pd target in a vacuumed aggregation chamber, the Mg target and the Pd target are independent neighboring targets; transporting the vapor including both of the super-saturated vapors of Pd and Mg to a vacuumed deposition chamber so that Pd nucleates and clusters first, followed by Mg nucleation and growth on the clustered Pd, surrounding the Pd cluster; thereafter, exposing resulting the Pd cluster surrounded by the grown Mg to oxygen to oxidize said surrounding Mg, thereby forming nanoparticles on a substrate in the deposition chamber, each of the nanoparticles consisting of one or more of a core made of Pd and a porous shell made of surrounding said one or more of the core, and changing a sputtering power ratio for the Pd target and the Mg target so as to create the nanoparticles of different sizes with different numbers of the core therein, wherein the changing of the sputtering power ratio includes: sputtering Pd and Mg from the Pd target and Mg target with respective sputtering powers for the Pd target and Mg target, and tailoring a thickness of the shell and a number of cores within each nanoparticle by adjusting respective sputtering powers of the Pd target and Mg target. 2. The method according to claim 1 , wherein the core made of single crystalline Pd and the shell made of polycrystalline MgO, and a Pd 3d 5/2 peak in an XPS survey spectrum of the nanoparticles shifts towards higher binding energy than that of Pd by a difference in electronegativities of Pd and Mg.