Enhancing sorption kinetics by oriented and single crystalline array-structured ZSM-5 film on monoliths

Weng, Junfei; Zhu, Chunxiang; Zhao, Binchao; Tang, Wenxiang; Lu, Xingxu; Liu, Fangyuan; Wu, Mudi; Ding, Yong; Gao, Pu-Xian

doi:10.1038/s41467-024-49672-5

Nat Commun

2024

DOI: 10.1038/s41467-024-49672-5

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Enhancing sorption kinetics by oriented and single crystalline array-structured ZSM-5 film on monoliths

Junfei Weng,

Chunxiang Zhu,

Binchao Zhao

et al.

Abstract: To enhance the reaction kinetics without sacrificing activity in porous materials, one potential solution is to utilize the anisotropic distribution of pores and channels besides enriching active centers at the reactive surfaces. Herein, by designing a unique distribution of oriented pores and single crystalline array structures in the presence of abundant acid sites as demonstrated in the ZSM-5 nanorod arrays grown on monoliths, both enhanced dynamics and improved capacity are exhibited simultaneously in prop… Show more

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Ultrathin PdAu Nanowires with High Alloying Degree for the Direct Oxidation of Methane to C1 Oxygenates

Tan,

Shi,

et al. 2024

Chin. J. Chem.

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Comprehensive SummaryThe direct oxidation of methane (CH4) into high‐valued C1 oxygenates production has garnered increased attention in effectively using vast CH4 and alleviating the global energy crisis. However, due to the high cleavage energy of C—H bond and low polarity of CH4 molecule, it is difficult to activate the first C—H bond. Furthermore, C1 oxygenates are readily inclined to be oxidized to CO2, because their weaker C—H bond comparing with CH4 molecule, resulting in poor selectivity. Herein, we designed ultrathin PdxAuy alloy NWs supported on ZSM‐5 (Z‐5) to investigate the direct oxidation of CH4 to high value‐added oxygenate under mild conditions. By precisely adjusting the molar ratio of Pd/Au and alloying degree, Pd9Au1NWs/Z‐5 showed an excellent yield of 11.57 mmol·g–l·h–1 and the outstanding selectivity of 95.1% for C1 oxygenates (CH3OH, CH3OOH and HCOOH). The in‐situ spectroscopic and mechanism analysis proved that the enhanced catalytic performance of Pd9Au1NWs/Z‐5 was ascribed to the stable one‐dimensional nanostructure and the strong synergy effect with high alloying PdAu, which could increase the adsorption capacity of CH4 molecules on Pd atoms to promote the CH4 conversion. This work offers valuable insights into the design concept of high‐efficient catalysts and the structure‐activity relationship for the direct oxidation of CH4.

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Ultrathin PdAu Nanowires with High Alloying Degree for the Direct Oxidation of Methane to C1 Oxygenates

Tan,

Shi,

et al. 2024

Chin. J. Chem.

View full text Add to dashboard Cite

show abstract

Hierarchically Structured Catalysts Toward Sustainable Hydrogen Economy: Electro‐ and Thermo‐Chemical Pathways

Deng,

Zhao,

Gao

2024

ChemSusChem

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Hydrogen, as an important clean energy source, plays a more and more crucial role in decarbonizing the planet and meeting the global climate challenge due to its high energy density and zero‐emission. The demand for sustainable hydrogen is increasing drastically worldwide as driven by the global shift towards low‐carbon energy solutions. Hierarchically structured catalysts and devices have gradually taken the center stage toward replacing the traditional counterparts, especially with the rapid advancing of the design and manufacture of such ordered nanostructure assemblies toward high activity, efficient mass transport, and superb stability. In this review, the latest progress of the hierarchically structured catalysts for hydrogen production have been surveyed on electro‐ and thermo‐ chemical pathways comparatively. It covers the structure designs of atomic dispersion, nanoscale surfaces and interfaces for achieving highly active and durable catalysts, components, and devices. Both electrochemical and thermochemical approaches are reviewed in terms of the vast design details, engineered benefits, and understandings of various Pt‐group metal (PGM) and non‐PGM based transition metal catalysts for hydrogen production. As the growing trend, brief discussions are also presented toward the high‐level assembly and manufacture of complexly structured components and devices at scale in the electrochemical and thermochemical energy systems.

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Enhancing sorption kinetics by oriented and single crystalline array-structured ZSM-5 film on monoliths

Cited by 2 publications

References 61 publications

Ultrathin PdAu Nanowires with High Alloying Degree for the Direct Oxidation of Methane to C1 Oxygenates

Ultrathin PdAu Nanowires with High Alloying Degree for the Direct Oxidation of Methane to C1 Oxygenates

Hierarchically Structured Catalysts Toward Sustainable Hydrogen Economy: Electro‐ and Thermo‐Chemical Pathways

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