Nanomaterials for CO2 Hydrogenation
The use of fossil fuels such as coal, oil, and natural gas has allowed a fast and unprecedented development of human society. However, this has led to a continuous increase in anthropogenic CO2 emissions, which affect human life and the ecological environment through global warming and climate chang...
- Autores:
-
Romero Sáez, Manuel
Jaramillo Zapata, Leyla Yamile
Henao Sierra, Wilson Albeiro
De La Torre Larrañaga, Unai
- Tipo de recurso:
- Part of book
- Fecha de publicación:
- 2019
- Institución:
- Tecnológico de Antioquia
- Repositorio:
- Repositorio Tdea
- Idioma:
- eng
- OAI Identifier:
- oai:dspace.tdea.edu.co:tdea/3975
- Acceso en línea:
- https://dspace.tdea.edu.co/handle/tdea/3975
- Palabra clave:
- Nanomaterials
Nanomateriales
Nanomatériau
Carbon monoxide
Monóxido de carbono
Oxyde de carbone
Methanol
Metanol
Methane
Metano
Carbon nanotubes
Nanotubos de Carbono
Nanotubes de carbone
Nanoparticles
Nanopartículas
Nanoparticules
CO2 hydrogenation
Hidrogenación de CO2
Carbon nanofibers
Nanofibras de carbono
Graphene oxide
Óxido de grafeno
Transition metal carbide
Carburo de metal de transición
- Rights
- closedAccess
- License
- http://purl.org/coar/access_right/c_14cb
Summary: | The use of fossil fuels such as coal, oil, and natural gas has allowed a fast and unprecedented development of human society. However, this has led to a continuous increase in anthropogenic CO2 emissions, which affect human life and the ecological environment through global warming and climate changes. There are various strategies to mitigate the atmospheric concentration of CO2, such as capture, separation, and utilization. Among them, CO2 hydrogenation to obtain different products through catalytic processes is a strategy of great interest. Thus, the catalytic combination of CO2 and hydrogen not only mitigates anthropogenic emissions into Earth’s atmosphere, but it also produces carbon compounds that can be used as fuel or precursors for the production of different chemicals. This chapter reviews the use of different nanomaterials for CO2 hydrogenation. Three different processes are distinguished, depending on the final product: (i) CO2 hydrogenation to carbon monoxide, (ii) methanol production by CO2 hydrogenation, and (iii) CO2 hydrogenation to methane. It has been included both nanomaterials that act as support and those that can replace the active metal phase. Concerning CO2 hydrogenation to CO, one-dimensional transition metal carbides have received increasing attention because their unique electronic structure allows similar catalytic properties to the expensive noble metals. Attending the high thermal requirements of CO synthesis, emerging metal oxides nanocatalysts are focused to prevent the metal sintering by increasing the metal-support interactions. Controlling the support’s morphology at nanoscale can enhance both catalytic activity and stability at high temperatures up to twice with respect to those conventional micro-sized catalysts. Regarding to methanol production, the nanomaterials most commonly used as supports are those based on carbon, e.g., carbon nanotubes, carbon nanofibers, and graphene oxide. The main advantage of using these materials is their high surface area, which improves metallic phase dispersion, higher thermal and electrical conductivities, and greater mechanical resistance. In addition, the use of intermetallic nanoparticles as an active phase is very promising. The combination of two metals in the same nanoparticle greatly increases the interface between components, which clearly leads to a synergistic effect between them. The use of these nanomaterials improves the activity and selectivity to methanol between 2 and ~50%, compared with classical catalysts. Moreover, similar strategies are equally valid in methane production. Catalysts based on nanoparticles, such as Ni or NiO, supported on traditional metal oxides have been recently reported to improve catalytic activity in CO2 methanation with high resistance to coke deposition. Other supports, such as carbon nanofibers and carbon nanotubes previously mentioned, have shown excellent results, with CO2 conversions higher than 90% and complete selectivity to methane. Finally, TiO2-based catalysts are a promising solution for methane production by the still undeveloped photocatalytic reduction. This reaction can be performed under mild temperatures and pressure conditions, which is a clear advantage for methane synthesis. Keywords CO2 hydrogenation Nanomaterials Carbon monoxide Methanol Methane Carbon nanotubes Carbon nanofibers Graphene oxide Nanoparticles Transition metal carbide |
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