Effects of alloying for steam or dry reforming of methane: a review of recent studies

Effects of alloying for steam or dry reforming of methane: a review of recent studies

Methane is an important chemical resource, not only in natural gas but also in biogas, which can be regarded as a renewable energy resource. Reforming of methane with steam or carbon dioxide, which is important for producing hydrogen and syngas, is conducted at high temperatures using heterogeneous...

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Veröffentlicht in:Catalysis science & technology 2022-06, Vol.12 (11), p.3387-3411
Hauptverfasser: Torimoto, Maki, Sekine, Yasushi
Format: Artikel
Sprache:eng
Schlagworte:
Alloying effects
Alternative energy sources
Biogas
Carbon
Carbon dioxide
Catalysts
Deposition
Electron states
Energy sources
High temperature
Hydrogen production
Low temperature
Methane
Natural gas
R&D
Reforming
Research & development
Secondary metals
Selectivity
Sintering
Sulfur
Synthesis gas
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creator Torimoto, Maki
Sekine, Yasushi
description Methane is an important chemical resource, not only in natural gas but also in biogas, which can be regarded as a renewable energy resource. Reforming of methane with steam or carbon dioxide, which is important for producing hydrogen and syngas, is conducted at high temperatures using heterogeneous catalysts. To achieve high activity, stability, and low carbon deposition, many studies have been conducted in recent years on the use of alloys as active sites in these catalysts. This review presents a summary of recent studies of alloy catalysts, for which various secondary metals have been added to active metals, such as Ni. Then we summarize the current status of these alloys in terms of their structure, electronic state, and adsorption. The reported effects of alloying include improvement of dispersion and reducibility of the supported metal, change in catalytic performance such as activity and selectivity, and improvement of durability against carbon deposition, sulphur poisoning, and sintering. The directions of future research and development are summarized in terms of sulphur resistance, sintering inhibition, and high activity at low temperatures. A survey on the catalytic nature of Ni-based alloy catalysts in recent years provides a direction for future catalyst development.
doi_str_mv 10.1039/d2cy00066k
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Reforming of methane with steam or carbon dioxide, which is important for producing hydrogen and syngas, is conducted at high temperatures using heterogeneous catalysts. To achieve high activity, stability, and low carbon deposition, many studies have been conducted in recent years on the use of alloys as active sites in these catalysts. This review presents a summary of recent studies of alloy catalysts, for which various secondary metals have been added to active metals, such as Ni. Then we summarize the current status of these alloys in terms of their structure, electronic state, and adsorption. The reported effects of alloying include improvement of dispersion and reducibility of the supported metal, change in catalytic performance such as activity and selectivity, and improvement of durability against carbon deposition, sulphur poisoning, and sintering. 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source Royal Society Of Chemistry Journals 2008-
subjects Alloying effects
Alternative energy sources
Biogas
Carbon
Carbon dioxide
Catalysts
Deposition
Electron states
Energy sources
High temperature
Hydrogen production
Low temperature
Methane
Natural gas
R&D
Reforming
Research & development
Secondary metals
Selectivity
Sintering
Sulfur
Synthesis gas
title Effects of alloying for steam or dry reforming of methane: a review of recent studies
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