Scientists from the Institute of Solid State Physics, Hefei Institutes of Physical Science developed the alfalfa-derived nitrogen (N)-doped porous carbon (NPC) fabricated by a pyrolysis method and it was electrocatalytically active for the NRR.
Electrosynthesis of ammonia (NH3) from the nitrogen (N2) reduction reaction (NRR) at ambient conditions has been widely regarded as a í░green NH3 synthesisí▒ technology to replace traditional energy- and capital-intensive Haber-Bosch process.
Until recently, metal-free N-doped porous graphitic carbon (NPGC) materialsmetal-free N-doped porous graphitic carbon (NPGC) materials as the electrocatalysts have demonstrated good NRR activities, promising for NH3 synthesis.
However, two main issues using the NPGC electrocatalysts for NRR still raise concern: one is the NRR active mechanism and another is if the doped N in NPGC catalyst will break away from the catalyst surface to contribute the NH3 formation during NRR.
It is well known that natural biomass resources provide sufficient raw materials for the future development and application of carbon materials because of their rich carbon content.
The results demonstrate that the doped pyridinic-N in NPC-500 catalyst during NRR could easily break away from its surface to form N vacancies in carbon matrix as the catalytic active sites for the NRR.
As a proof of concept experiment, they further utilized the NPC-500 assembled Zn-air battery to drive the NPC-500 constructed two-electrode NRR cell, giving a high NH3 yield rate and Faradaic efficiency.
The findings in this work demonstrates the feasibility of utilizing biomass-derived carbon electrocatalyst for energy-integrated electrosynthesis of NH3 from the N2 reduction reaction at ambient conditions.
Link to the paper: Ambient Electrosynthesis of Ammonia on a Biomass-Derived Nitrogen-Doped Porous Carbon Electrocatalyst: Contribution of Pyridinic Nitrogen
Figure (A) A schematic illustration of the fabrication process, and the SEM images of as-prepared electrodes; (B) Conversion and yield (%) changes of furfural and its oxidation/hydrogenation products, and schematic diagram of two-electrode electrocatalytic conversion of furfural. (C) Mass spectra of furfural and its products obtained in H2O/NaOH and D2O/NaOH. (D) The schematics illustrating the ECH and HER at catalyst surface.(Image by ZHANG Xian)