Facile synthesis of NS@UiO-66 porous carbon for efficient oxygen reduction reaction in microbial fuel cells

“…The current density of the NS@UiO-66 composite can reach 5.79 mA cm −2 , which is close to the benchmark Pt/C catalyst ( J L = 5.59 mA cm −2 ). 26 Zhao and Xia noted that the synergistic interaction between N and S reduced the overpotential and stabilized the adsorbate, resulting in fast ORR kinetics. 27 Besides simple carbon coating, carbon nanotubes (CNTs) as the most desirable catalyst carrier materials have also been applied to achieve alloy cladding due to their excellent electrical conductivity, chemical stability, large specific surface area, mechanical strength and accessibility.…”

“…The current density of the NS@UiO-66 composite can reach 5.79 mA cm −2 , which is close to the benchmark Pt/C catalyst ( J L = 5.59 mA cm −2 ). 26 Zhao and Xia noted that the synergistic interaction between N and S reduced the overpotential and stabilized the adsorbate, resulting in fast ORR kinetics. 27…”

Structural design of FeCo alloy implanted into N,S co-doped carbon nanotubes via self-catalyzed growth for advanced liquid and flexible all-state-state Zn–air battery

“…The current density of the NS@UiO-66 composite can reach 5.79 mA cm −2 , which is close to the benchmark Pt/C catalyst ( J L = 5.59 mA cm −2 ). 26 Zhao and Xia noted that the synergistic interaction between N and S reduced the overpotential and stabilized the adsorbate, resulting in fast ORR kinetics. 27 Besides simple carbon coating, carbon nanotubes (CNTs) as the most desirable catalyst carrier materials have also been applied to achieve alloy cladding due to their excellent electrical conductivity, chemical stability, large specific surface area, mechanical strength and accessibility.…”

“…The current density of the NS@UiO-66 composite can reach 5.79 mA cm −2 , which is close to the benchmark Pt/C catalyst ( J L = 5.59 mA cm −2 ). 26 Zhao and Xia noted that the synergistic interaction between N and S reduced the overpotential and stabilized the adsorbate, resulting in fast ORR kinetics. 27…”

Structural design of FeCo alloy implanted into N,S co-doped carbon nanotubes via self-catalyzed growth for advanced liquid and flexible all-state-state Zn–air battery

Metal–Organic Frameworks Derived Carbon‐Supported Metal Electrocatalysts for Energy‐Related Reduction Reactions

Metal–Organic Frameworks Derived Carbon‐Supported Metal Electrocatalysts for Energy‐Related Reduction Reactions