Unveiling N-doped carbon nitride aerogel for efficient electrocatalytic water splitting application

IF 2.5 4区材料科学 Q2 CHEMISTRY, APPLIED

Journal of Porous Materials Pub Date : 2024-11-14 DOI:10.1007/s10934-024-01711-8

Sapna B. Jadhav, Manjiri Thakur, Pradip. B. Sarawade

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Abstract

The porous carbon nitrides (CN) aerogel was developed with a sol-gel method followed by ambient pressure drying technique and calcination, where catalysts were deposited on nickel foam for the Hydrogen Evolution Reaction (HER). However, the low conductivity of carbon structure and an expensive production process hinder the practical approach of carbon nitrides as catalysts. Herein, nickel foam-supported N-doped porous carbon aerogel samples are constructed with high catalytic activity toward HER in an alkaline medium. As-prepared carbon nitride aerogel (CN@800) has a high specific surface area (570 cm².g^− 1), and a large pore size distribution (180 nm). Performance of abundant CN active sites and the synergistic effect of N-doped porous carbon aerogels: the CN exhibits small overpotentials of CN@200, CN@600, and CN@800 of -206, -218, and − 180 mV at 10 mA.cm² with Tafel values of 109, 120, and 107 mV.dec^− 1 towards HER, respectively. Compared to the conventional approach, our electrocatalyst of sol-gel-based porous carbon nitrate aerogel can deliver high hydrogen production efficiency.

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揭示用于高效电催化水分解的氮化碳气凝胶

采用溶胶-凝胶法制备多孔氮化碳（CN）气凝胶，然后采用常压干燥和煅烧技术，将催化剂沉积在泡沫镍上进行析氢反应（HER）。然而，碳结构的低电导率和昂贵的生产工艺阻碍了氮化碳作为催化剂的实际应用。本文构建了泡沫镍负载的n掺杂多孔碳气凝胶样品，在碱性介质中对HER具有高催化活性。制备的氮化碳气凝胶（CN@800）具有高比表面积（570 cm2.g−1）和大孔径分布（180 nm）。丰富CN活性位点的性能和n掺杂多孔碳气凝胶的协同效应：CN在10 mA时表现出-206、-218和- 180 mV的小过电位CN@200、CN@600和CN@800。Tafel值分别为109、120和107 mV.dec−1。与传统方法相比，我们的溶胶-凝胶基多孔硝酸碳气凝胶电催化剂具有更高的制氢效率。

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来源期刊

Journal of Porous Materials 工程技术-材料科学：综合

CiteScore

4.80

自引率

7.70%

发文量

203

审稿时长

2.6 months

期刊介绍： The Journal of Porous Materials is an interdisciplinary and international periodical devoted to all types of porous materials. Its aim is the rapid publication of high quality, peer-reviewed papers focused on the synthesis, processing, characterization and property evaluation of all porous materials. The objective is to establish a unique journal that will serve as a principal means of communication for the growing interdisciplinary field of porous materials. Porous materials include microporous materials with 50 nm pores. Examples of microporous materials are natural and synthetic molecular sieves, cationic and anionic clays, pillared clays, tobermorites, pillared Zr and Ti phosphates, spherosilicates, carbons, porous polymers, xerogels, etc. Mesoporous materials include synthetic molecular sieves, xerogels, aerogels, glasses, glass ceramics, porous polymers, etc.; while macroporous materials include ceramics, glass ceramics, porous polymers, aerogels, cement, etc. The porous materials can be crystalline, semicrystalline or noncrystalline, or combinations thereof. They can also be either organic, inorganic, or their composites. The overall objective of the journal is the establishment of one main forum covering the basic and applied aspects of all porous materials.