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Highly Active and Robust Catalyst: Co<sub>2</sub>B–Fe<sub>2</sub>B Heterostructural Nanosheets with Abundant Defects for Hydrogen Production

Shuqing Zhou, Lianrui Cheng, Yi Liu, Jianniao Tian, Chenggong Niu, Wei Li, Shoulei Xu, Tayirjan Taylor Isimjan, Xiulin Yang

2024Inorganic Chemistry22 citationsDOI

Abstract

A high-performance and reusable nonnoble metal catalyst for catalyzing sodium borohydride (NaBH 4 ) hydrolysis to generate H 2 is heralded as a nuclear material for the fast-growing hydrogen economy. Boron vacancy serves as a flexible defect site that can effectively regulate the catalytic hydrolysis performance. Herein, we construct a uniformly dispersed and boron vacancy-rich nonnoble metal Co 2 B–Fe 2 B catalyst via the hard template method. The optimized Co 2 B–Fe 2 B exhibits superior performance toward NaBH 4 hydrolysis, with a high hydrogen generation rate (5315.8 mL min –1 g catalyst –1 ), relatively low activation energy (35.4 kJ mol –1 ), and remarkable cycling stability, outperforming the majority of reported catalysts. Studies have shown that electron transfer from Fe 2 B to Co 2 B, as well as abundant boron defects, can effectively modulate the charge carrier concentration of Co 2 B–Fe 2 B catalysts. Density functional theory calculations confirm that the outer electron cloud density of Co 2 B is higher than that of Fe 2 B, among which Co 2 B with high electron cloud density can selectively adsorb BH 4 – ions, while the electron-deficient Fe 2 B is favorable for capturing H 2 O molecules, therefore synergistically promoting the catalytic NaBH 4 hydrolysis to produce H 2 .

Topics & Concepts

CatalysisChemistrySodium borohydrideBoronHydrolysisHydrogen productionHydrogenNon-blocking I/OChemical engineeringOrganic chemistryEngineeringHydrogen Storage and MaterialsAmmonia Synthesis and Nitrogen ReductionSuperconductivity in MgB2 and Alloys