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Practical H2 supply from ammonia borane enabled by amorphous iron domain

Yufeng Chen, Zhongling Lang, Kun Feng, Kang Wang, Yang‐Guang Li, Zhenhui Kang, Lin Guo, Jun Zhong, Jun Lü

2024Nature Communications21 citationsDOIOpen Access PDF

Abstract

Efficient catalysis of ammonia borane (AB) holds potential for realizing controlled energy release from hydrogen fuel and addressing cost challenges faced by hydrogen storage. Here, we report that amorphous domains on metallic Fe crystal structures (R-Fe2O3 Foam) can achieve AB catalytic performances and stability (turnover frequency (TOF) of 113.6 min−1, about 771 L H2 in 900 h, and 43.27 mL/(min·cm2) for 10×10 cm2 of Foam) that outperform reported benchmarks (most <14 L H2 in 45 h) by at least 20 times. These notable increases are enabled by the stable Fe crystal structure, while defects and unsaturated atoms in the amorphous domains form Fe-B intermediates that significantly lower the dissociation barriers of H2O and AB. Given that the catalyst lifetime is a key determinant for the practical use in fuel cells, our R-Fe2O3 Foam also provides decent H2 supply (180 mL H2/min, AB water solution of 7.5 wt% H2) in a driven commercial car fuel cell at stable power outputs (7.8 V and 1.6 A for at least 5 h). When considered with its facile synthesis method, these materials are potentially very promising for realizing durable high-performance AB catalysts and viable chemical storage in hydrogen powered vehicles. Hydrogen storage and release are critical issues for commercial use. Here, authors report a Fe Foam with amorphous domains for the hydrolysis of ammonia borane with ultra-long lifetime over 900 h, realizing the on-board H2 supply of a model car.

Topics & Concepts

Ammonia boraneAmmoniaAmorphous solidDomain (mathematical analysis)ChemistryBoraneComputer scienceNanotechnologyMaterials scienceBiochemistryHydrogenCrystallographyHydrogen storageCatalysisOrganic chemistryMathematicsMathematical analysisHydrogen Storage and MaterialsAmmonia Synthesis and Nitrogen ReductionElectrocatalysts for Energy Conversion