PtNi@ZIF-8 nanocatalyzed high efficiency and complete hydrogen generation from hydrazine borane: origin and mechanistic insight

The rational design of highly efficient nanocatalysts and understanding of the hydrogen generation process for selective and complete decomposition of hydrazine borane (HB) remain challenging. Here, a series of monodispersed, ultrasmall, highly efficient Pt x Ni y alloyed nanoparticles were prepared...

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Published in:Journal of materials chemistry. A, Materials for energy and sustainability Materials for energy and sustainability, 2022-08, Vol.1 (34), p.17614-17623
Main Authors: Wang, Changlong, Liu, Xiang, Wu, Yufeng, Astruc, Didier
Format: Article
Language:English
Subjects:
Alloying
Cascade chemical reactions
Catalysts
Decomposition
Design optimization
Energy gap
Free energy
Gas evolution
Gibbs free energy
Hydrazine
Hydrazine borane
Hydrogen
Hydrogen evolution
Hydrogen production
Hydrogen storage materials
Intermetallic compounds
Metals
Nanoalloys
Nanoparticles
Platinum
Volcanoes
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Summary:The rational design of highly efficient nanocatalysts and understanding of the hydrogen generation process for selective and complete decomposition of hydrazine borane (HB) remain challenging. Here, a series of monodispersed, ultrasmall, highly efficient Pt x Ni y alloyed nanoparticles were prepared using ZIF-8 as the MOF template. Upon scrutinizing the optimal Pt, Ni and support proportions, remarkable synergy of volcano-type is disclosed between these two metals in their alloy and with the ZIF-8 support. The high catalyst efficiency with complete gas evolution is among the best ever recorded, also showing promising utilization of this catalyst in other tandem reactions involving hydrogen. The experimental and DFT simulation results indicate that alloying Pt with Ni in PtNi@ZIF-8 with an optimized surface d-band center optimizes absorption and activation of the HB molecule, thereby reducing the energy barrier of the hydrolysis of the BH 3 group in HB. By systemically comparing the hydrolytic decomposition processes of HB over the nanocatalysts PtNi@ZIF-8 and RhNi@ZIF-8, the desorption of the borate is identified as the rate-determining step. In the following decomposition of the N 2 H 4 moiety, the nanocatalyst PtNi@ZIF-8 always shows a smaller Gibbs free energy gap than RhNi@ZIF-8, rationalizing the faster kinetics for complete hydrogen evolution. The principle and results generated in the present study should contribute to optimizing the design of highly efficient nanocatalysts for hydrogen generation from hydrogen storage materials. The rational design of highly efficient PtNi@ZIF-8 nanocatalyst and the understanding of the hydrogen generation process for selective and complete decomposition of hydrazine borane (HB) are disclosed.
ISSN:2050-7488
2050-7496
DOI:10.1039/d2ta04411k