Synergetic Cu0 and Cu+ on the surface of Al2O3 support enhancing methanol steam reforming reaction

•Cu0-Cu+ synergetic path avoids the rate-determining step on Cu0 or Cu+ single sites.•HCHO migration from Cu0 NPs to Cu+ is crucial for constructing the synergy path.•Cu_9% exhibits preferable activity attribute to optimal amount and ratio of Cu0-Cu+. The methanol steam reforming (MSR) reaction was...

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Published in:Surfaces and interfaces 2024-08, Vol.51, p.104633, Article 104633
Main Authors: Liu, Xue, Wang, Kai, Ran, Qian, Liu, Zongming, Wang, Lipeng, Wang, Min, Li, Qi, Cao, Daofan, Wu, Changning, Liu, Ke
Format: Article
Language:English
Subjects:
Copper loading
Cu0-Cu+ synergy sites
Cu0/Cu+ ratio
Methanol steam reforming
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Summary:•Cu0-Cu+ synergetic path avoids the rate-determining step on Cu0 or Cu+ single sites.•HCHO migration from Cu0 NPs to Cu+ is crucial for constructing the synergy path.•Cu_9% exhibits preferable activity attribute to optimal amount and ratio of Cu0-Cu+. The methanol steam reforming (MSR) reaction was a crucial pathway for hydrogen production, with Cu-based catalysts widely applied. It was established that the isolated Cu0-site path and Cu+-site path were responsible for methanol conversion. However, a “Seesaw Effect” existed between the activation of *CH3O and the formation of CO2. Specifically, Cu0 site favored *CH3O activation but facilitated the reverse water gas shift (RWGS) process. Conversely, Cu+ site suppressed CO and promoted CO2 formation but had a reduced ability for *CH3O dehydrogenation. In this work, a Cu0-Cu+ synergy path was proposed, Cu0 sites activate CH3OH into *CH2O, and the subsequent conversion of *CH2O is catalyzed over the Cu+ site. Characterization and calculation results demonstrated that this synergy path subtly avoids two rate-determining steps (*CH3O → *CH2O on Cu+ sites and bi-*CHOO → *CO2 on Cu0 site). The migration of *CH2O from the Cu0 site to Cu+ sites was a critical step in constructing a synergy path. Moreover, MSR performance was governed by the quantity of synergy sites (Cu0/Cu+) and the amount of matched Cu0-Cu+ sites, both of which could be adjusted by varying the Cu loading (1–20%). An optimal 9% Cu enhanced the synergy interaction, with a Cu0/Cu+ ratio of 1.2 and the highest amount of Cu0-Cu+ sites (609.4 μmol/g), giving rise to high methanol conversion and low CO concentration. The discovery in this work provided theoretical guidance for constructing high-performance Cu-based catalysts. [Display omitted]
ISSN:2468-0230
2468-0230
DOI:10.1016/j.surfin.2024.104633