Ru-Based Catalysts for Ammonia Decomposition: A Mini-Review

Ammonia with a hydrogen content of 17.6 wt % is viewed as a promising hydrogen carrier because the infrastructures for its production, storage, and transportation have been well established. The challenge is that currently the straight production of H2 from NH3 only works at high temperatures. To da...

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Published inEnergy & fuels Vol. 35; no. 15; pp. 11693 - 11706
Main Authors Chen, Chongqi, Wu, Kai, Ren, Hongju, Zhou, Chen, Luo, Yu, Lin, Li, Au, Chaktong, Jiang, Lilong
Format Journal Article
LanguageEnglish
Published American Chemical Society 05.08.2021
Subjects
ammonia
catalysts
catalytic activity
energy
graphene
hydrogen
reaction mechanisms
structure-activity relationships
temperature
transportation
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Abstract Ammonia with a hydrogen content of 17.6 wt % is viewed as a promising hydrogen carrier because the infrastructures for its production, storage, and transportation have been well established. The challenge is that currently the straight production of H2 from NH3 only works at high temperatures. To date, various metal-based catalysts have been developed for NH3 decomposition, among which the Ru-based ones are the most superior due to the suitable Ru–N binding energy. In the past decade, efforts have been put in to improve the performance of Ru-based catalysts, and the target is to lower Ru loading and reaction temperature. A large variety of support and promoter materials were studied, and advanced techniques were employed to disclose the relationship between catalytic performance and catalyst structure. In this paper, we conduct a review on the materials that are used as supports and/or promoters, focusing specifically on the carbon (CNTs, CNFs, and graphene) and metal oxide (Al2O3, MgO, SiO2, and others) materials. Moreover, the reaction mechanism for ammonia decomposition over Ru-based catalysts is described, and future works on designing novel catalysts and unravelling the catalyst structure–activity relationship are proposed.
AbstractList Ammonia with a hydrogen content of 17.6 wt % is viewed as a promising hydrogen carrier because the infrastructures for its production, storage, and transportation have been well established. The challenge is that currently the straight production of H2 from NH3 only works at high temperatures. To date, various metal-based catalysts have been developed for NH3 decomposition, among which the Ru-based ones are the most superior due to the suitable Ru–N binding energy. In the past decade, efforts have been put in to improve the performance of Ru-based catalysts, and the target is to lower Ru loading and reaction temperature. A large variety of support and promoter materials were studied, and advanced techniques were employed to disclose the relationship between catalytic performance and catalyst structure. In this paper, we conduct a review on the materials that are used as supports and/or promoters, focusing specifically on the carbon (CNTs, CNFs, and graphene) and metal oxide (Al2O3, MgO, SiO2, and others) materials. Moreover, the reaction mechanism for ammonia decomposition over Ru-based catalysts is described, and future works on designing novel catalysts and unravelling the catalyst structure–activity relationship are proposed.
Ammonia with a hydrogen content of 17.6 wt % is viewed as a promising hydrogen carrier because the infrastructures for its production, storage, and transportation have been well established. The challenge is that currently the straight production of H₂ from NH₃ only works at high temperatures. To date, various metal-based catalysts have been developed for NH₃ decomposition, among which the Ru-based ones are the most superior due to the suitable Ru–N binding energy. In the past decade, efforts have been put in to improve the performance of Ru-based catalysts, and the target is to lower Ru loading and reaction temperature. A large variety of support and promoter materials were studied, and advanced techniques were employed to disclose the relationship between catalytic performance and catalyst structure. In this paper, we conduct a review on the materials that are used as supports and/or promoters, focusing specifically on the carbon (CNTs, CNFs, and graphene) and metal oxide (Al₂O₃, MgO, SiO₂, and others) materials. Moreover, the reaction mechanism for ammonia decomposition over Ru-based catalysts is described, and future works on designing novel catalysts and unravelling the catalyst structure–activity relationship are proposed.
Author Ren, Hongju
Wu, Kai
Zhou, Chen
Luo, Yu
Chen, Chongqi
Jiang, Lilong
Lin, Li
Au, Chaktong
AuthorAffiliation National Engineering Research Center of Chemical Fertilizer Catalyst
AuthorAffiliation_xml – name: National Engineering Research Center of Chemical Fertilizer Catalyst
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Snippet Ammonia with a hydrogen content of 17.6 wt % is viewed as a promising hydrogen carrier because the infrastructures for its production, storage, and...
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acs
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SubjectTerms ammonia
catalysts
catalytic activity
energy
graphene
hydrogen
reaction mechanisms
structure-activity relationships
temperature
transportation
Title Ru-Based Catalysts for Ammonia Decomposition: A Mini-Review
URI http://dx.doi.org/10.1021/acs.energyfuels.1c01261
https://www.proquest.com/docview/2636478943
Volume 35
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