Multichannel nitrogen-doped carbon fiber confined Fe3C nanoparticles for efficient electroreduction of nitrate†

EES catalysis Pub Date : 2024-02-05 DOI:10.1039/D4EY00016A
Fangzhou Zhang, Zhangsheng Shi, Junliang Chen, Hongxia Luo, Jun Chen and Jianping Yang
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Abstract

Electrochemical conversion of nitrate into benign dinitrogen is a promising solution for water purification and environmental remediation. The development of environmentally friendly electrocatalysts possessing excellent catalytic activity and stability has attracted increasing attention. Herein, a 1D hierarchical architecture with uniformly dispersed Fe3C nanoparticles confined in multichannel nitrogen-doped carbon fibers (Fe3C/MNCFs) is reported as a highly efficient NO3RR electrocatalyst. Fe3C/MNCFs-800 demonstrates a nitrate conversion of 90.9%, an N2 selectivity of 99.53%, and up to 15 cycles of electrocatalytic stability. The excellent electrocatalytic activity is proposed to be mainly due to the multichannel fibrous architecture beneficial for exposing more active sites and facilitating mass diffusion. Moreover, the strong interaction between active species and fibrous support guarantees the chemical stability and long cycle life. This work provides a reference for the development of high-performance noble-metal-free electrocatalysts for eco-friendly nitrate reduction.

Abstract Image

包含 Fe3C 纳米粒子的多通道掺氮碳纤维用于硝酸盐的高效电还原
通过电化学方法将硝酸盐转化为良性二氮是一种前景广阔的水净化和环境修复解决方案。开发具有优异催化活性和稳定性的环境友好型电催化剂日益受到关注。本文报告了一种高效 NO3RR 电催化剂,它是由均匀分散的 Fe3C 纳米颗粒组成的一维分层结构,并将其封闭在多通道掺氮碳纤维(Fe3C/MNCFs)中。Fe3C/MNCFs-800 的硝酸盐转化率为 90.9%,对 N2 的选择性为 99.53%,并且具有长达 15 个循环的电催化稳定性。卓越的电催化活性主要归功于多通道纤维结构有利于暴露更多的活性位点并促进质量扩散。此外,活性物质与纤维支撑之间的强相互作用保证了化学稳定性和长循环寿命。这项工作为开发用于环保型硝酸盐还原的高性能无惰性金属电催化剂提供了参考。
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