Optimizing biogas methanation over nickel supported on ceria-alumina catalyst: Towards CO2-rich biomass utilization for a negative emissions society

Biogas methanation emerges as a prominent technology for converting biogas into biomethane in a single step. Furthermore, this technology can be implemented at biogas plant locations, supporting local economies and reducing dependence on large energy producers. However, there is a lack of comprehens...

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Bibliographic Details
Published in:Environmental research 2024-02, Vol.242, p.117735-117735, Article 117735
Main Authors: González-Arias, J., Torres-Sempere, G., Arroyo-Torralvo, F., Reina, T.R., Odriozola, J.A.
Format: Article
Language:English
Subjects:
Biogas methanation
Biomass
CO2 waste valorization
Methanation
Ni-based catalyst
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Summary:Biogas methanation emerges as a prominent technology for converting biogas into biomethane in a single step. Furthermore, this technology can be implemented at biogas plant locations, supporting local economies and reducing dependence on large energy producers. However, there is a lack of comprehensive studies on biogas methanation, particularly regarding the technical optimization of operational parameters and the profitability analysis of the overall process. To address this gap, our study represents a seminal work on the technical optimization of biogas methanation obtaining an empirical model to predict the performance of biogas methanation. We investigate the influence of operational parameters, such as reaction temperature, H2/CO2 ratio, space velocity, and CO2 share in the biogas stream through an experimental design. Based on previous research we selected a nickel supported on ceria-alumina catalyst; being nickel a benchmark system for methanation process such selection permits a reliable data extrapolation to commercial units. We showcase the remarkable impact of studied key operation parameters, being the temperature, the most critical factor affecting the reaction performance (ca. 2 to 5 times higher than the second most influencing parameter). The impact of the H2/CO2 ratio is also noticeable. The response surfaces and contour maps suggest that a temperature between 350 and 450 °C and an H2/CO2 ratio between 2.5 and 3.2 optimize the reaction performance. Further experimental tests were performed for model validation and optimization leading to a reliable predictive model. Overall, this study provides validated equations for technology scaling-up and techno-economic analysis, thus representing a step ahead towards real-world applications for bio-methane production. •An empirical model to predict the performance of biogas methanation was built.•The influence of the main operational parameters was studied.•The temperature is the most critical factor affecting the reaction performance.•The impact of the H2/CO2 ratio is also noticeable.•Temperature of 350–450 °C and H2/CO2 ratio of 2.5–3.2 optimize the reaction.
ISSN:0013-9351
1096-0953
DOI:10.1016/j.envres.2023.117735