AI Article Synopsis
- A solution is proposed to address the energy crisis and pollution by creating efficient and durable electrocatalysts for hydrogen production through water splitting.
- Graphene-based materials, particularly reduced graphene oxide (rGO), are enhanced by embedding them in a stable SiO matrix to improve performance and stability.
- The developed rGO/SiO composite shows impressive electrocatalytic activity, with low overpotential and excellent durability, making it a promising and cost-effective choice for hydrogen evolution reactions.
Article Abstract
To mitigate the energy crisis and environmental pollution, efficient and earth-abundant hydrogen evolution reaction (HER) electrocatalysts are essential for hydrogen production through electrochemical water splitting. Graphene-based materials as metal-free catalysts have attracted significant attention but suffer from insufficient activity and stability. Therefore, a novel and economical approach is developed to prepare highly active, robust, and self-supported reduced graphene oxide (rGO)/SiO ceramic composites as electrocatalysts in HER. Through intercalation and pressure sintering, the rGO sheets are parallelly aligned and embedded into a dense and chemically inert SiO matrix, ensuring the electrical conductivity and stability of the prepared composites. After directional cutting, the edges of the oriented rGO sheets become fully exposed on the composite surface, acting as highly electrocatalytic active sites in HER, as confirmed by density functional theory calculations. The 4 vol% rGO/SiO composite displays superior electrocatalytic performance, featuring a low overpotential (134 mV) at a current density of 10 mA cm , a small Tafel slope (103 mV dec ), and excellent catalytic durability in 0.5 m H SO . This study provides a new yet cost-effective strategy to prepare metal-free, robust, and edge-rich rGO/ceramic composites as a highly electrocatalytic active catalyst for HER applications.
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| http://dx.doi.org/10.1002/smtd.202100621 | DOI Listing |
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