Direct Vat‐Photopolymerization 3D Printing of Hierarchically Porous SiC Loaded with Co/Ni Based Catalysts by Using Pickering Emulsions

Hierarchically porous silicon carbide (SiC) is an important catalyst support widely used in various gas and liquid catalytic processes. Conventional approaches to fabricate such SiC have limited design flexibility and separated catalyst‐loading step is necessitated. Herein, a one‐step, direct vat‐photopolymerization 3D printing of hierarchically porous SiC loaded with Co/Ni based catalyst is demonstrated with Pickering emulsion as feedstock for the first time. Compared with normal ceramic slurries, Pickering emulsion dramatically increases the cure depth (by 50%) and emulsion stability, which allow continuous printing of complex SiC structures with uniform pore morphology. The resultant hierarchical porous SiC offered ≈40% better mechanical strength as compared with non‐hierarchical counterpart. By dissolving metal salts into aqueous phase in Pickering emulsions, complex architected structures with Co or Ni/Co in situ loaded in SiC matrix are printed. The metal salts are then thermally converted into oxides or silicates as catalysts anchored on SiC, exhibiting excellent catalytic activity and reusability. The emulsion templating strategy holds great facility to load various highly attractive materials such as high entropy oxides or functional fillers whilst reaping the benefits of vat photopolymerization for a myriad of applications in catalysis, batteries, and structural supports. Direct vat‐photopolymerization 3D printing of hierarchically porous SiC in‐situ loaded with Co/Ni is demonstrated by using Pickering emulsion feedstock with Co/Ni salts dissolved in its aqueous phase. The metal salts can be thermally converted into oxide or silicate catalyst, exhibiting excellent catalytic activity and reusability. The resultant hierarchically porous SiC also offers ≈40% better mechanical strength than non‐hierarchical counterpart.