Hollow polyhedral Fe-N-C nanostructures derived from ZIF-8 highlighting markable morphology effect on electrochemical oxygen reduction and carbon dioxide reduction

“…Two broad peaks are detected at about 21.9°a nd 45.1°for all samples, which correspond to the (002) and (101) planes of graphitic carbon. [45][46][47] No diffraction peak related to Fe-containing species is observed in the XRD patterns of 0.2FeNC-OAc and 0.2FeNC. With the increase of the Fe doping amount, a noticeable diffraction peak at 26.5°and a few weak diffraction peaks at 43.1-45.8°from Fe 3 C are observed for the 0.8FeNC-OAc and 1.6FeNC-OAc catalysts, which indicates that a large number of Fe ions at high temperature can reunite to form large Fe-related particles.…”

Carboxylate trapping engineering to fabricate monodispersed dual-atom iron sites for efficient oxygen reduction

“…Two broad peaks are detected at about 21.9°a nd 45.1°for all samples, which correspond to the (002) and (101) planes of graphitic carbon. [45][46][47] No diffraction peak related to Fe-containing species is observed in the XRD patterns of 0.2FeNC-OAc and 0.2FeNC. With the increase of the Fe doping amount, a noticeable diffraction peak at 26.5°and a few weak diffraction peaks at 43.1-45.8°from Fe 3 C are observed for the 0.8FeNC-OAc and 1.6FeNC-OAc catalysts, which indicates that a large number of Fe ions at high temperature can reunite to form large Fe-related particles.…”

Carboxylate trapping engineering to fabricate monodispersed dual-atom iron sites for efficient oxygen reduction

Highly Dispersed Palladium Nanoparticles on Carbon Doping with Nitrogen Derived from MOFs for 4‐Nitrophenol Hydrogenation

Mn/Co co-doped porous carbon material derived from self-assembly of CoPc and ZIF-11 for oxygen reduction reaction