An exfoliated iron phosphorus trisulfide nanosheet with rich sulfur vacancy for efficient dinitrogen fixation and Zn-N2 battery

Two-dimensional (2D) transition metal compounds have been explored as promising catalysts in dinitrogen electroreduction (NRR) for ammonia synthesis, while the immense basal planes of the 2D materials are inert towards the electrocatalysis. Herein, we report a porous exfoliated FePS3 nanosheet with rich sulfur vacancy (Vs-FePS3 NSs) synthesized by electrochemical exfoliation and hydrogenation treatment. Owing to the rich sulfur vacancy and unique 2D morphology with a thickness of similar to 15 nm and lateral dimension of similar to 500 nm, Vs-FePS3 NSs show an excellent activity in electrochemical NRR with a high Faradaic efficiency of 12.36% at 0.20 V and an ammonia yield rate of 3.88 mu g h(-1) cm(-2) at 0.25 V versus reversible hydrogen electrode in acid. Experimental observations reveal the Fe species as real active sites and S vacancies for hydrogenation of N-2 toward a synergistic effect for enhanced NRR. In addition, Vs-FePS3 NSs can serve as the cathode of a Zn-N-2 battery to achieve a power density of 2.6 mW cm(-2).

Automated summary

A porous exfoliated FePS3 nanosheet with rich sulfur vacancy (Vs-FePS3 NSs) synthesized by electrochemical exfoliation and hydrogenation treatment shows excellent activity in electrochemical NRR. The Fe species are identified as the real active sites, and S vacancies play a role in enhancing the NRR process. Vs-FePS3 NSs can also serve as the cathode of a Zn-N-2 battery with a power density of 2.6 mW cm(-2).