Boron doping and high curvature in Bi nanorolls for promoting photoelectrochemical nitrogen fixation

Photoelectrochemical (PEC) nitrogen reduction reaction (NRR), which produces ammonia under ambient conditions by combining the merits of electmcatalysis and photocatalysis, represents an attractive prospect for nitrogen fixation. Limited by the choice of suitable p-type semiconductor, PEC nitrogen fixation should be preferentially achieved by cathodic NRR integrated with photoanode rather than direct photocathodic NRR. Even in such an approach, it still remains elusive how to design catalytically active sites on the dark cathode toward high activity and selectivity in PEC NRR. Herein, we report a new strategy for tailoring cathodic bismuth (Bi) sites with boron (B) doping and rolling curvature. The B doping in Bi matrix greatly reduces the energy barrier of the potential-determining step of N-2 ->*NNH in NRR while the high curvature surface on nanorolls facilitates the adsorption of N-2. The integration of B doping and rolling curvature in a single cathodic catalyst boosts PEC NRR performance when combined with TiO2 nanorods array as photoanode to harvest light and provide photo-generated electrons. Such a PEC system offers an ammonia yield rate of 29.2 mg(NH3)g(cat)(-1)h(-1) and Faradaic efficiency of 8.3 % at a bias of 0.48 V versus RHE in nitrogen fixation. This work provides a guideline for the rational design of highly active and selective metallic catalyst in PEC NRR.

Automated summary

This research presents a new strategy for tailoring cathodic bismuth sites with boron doping and rolling curvature to enhance PEC NRR performance, providing guidance for rational design of highly active and selective metallic catalyst in PEC NRR.