Tobacco stem-derived nitrogen-containing porous carbon with highly dispersed Ni-N sites as an efficient electrocatalyst for CO reduction to CO

Electrochemical CO 2 reduction is considered as a promising strategy for CO 2 conversion and utilization. However, developing efficient and low-cost electrocatalysts still remains a great challenge. Herein, Ni-N@NPC was prepared using tobacco stem derived nitrogen-containing porous carbon (NPC) as a support and 1,10 phenanthroline as a chelating agent, as well as nickel( ii ) acetate tetrahydrate as a Ni source. The prepared Ni-N@NPC has highly dispersed Ni-N sites and good CO 2 adsorption capacity. Ni-N@NPC exhibits excellent electrochemical CO 2 reduction property, including high faradaic efficiency for CO (about 98.44%) at a medium overpotential of 670 mV and high activity (current density approximately 30.96 mA cm −2 ), as well as durable stability over 30 hours. In addition, the Ni-N@NPC still maintains a Faraday efficiency over 90.5% at wide potentials (from −0.57 V to −0.87 V). DFT calculation reveals that Ni-N sites decrease the kinetic energy barriers for *CO 2 transition to *COOH, indicating that the high electrochemical CO 2 reduction activity is attributed to the Ni-N sites in electrocatalysts. This work provides a new way to develop biomass carbon materials and promote their application in energy conversion. A cost-effective electrocatalyst with highly dispersed Ni-N sites was prepared by tobacco stem-derived nitrogen-containing porous carbon.