Insights into reactive behaviors and mechanisms of nickel-based oxygen carriers doped by Fe/Co during chemical looping combustion from multiple-scale molecular modeling combined with experiments

Insights into reactive behaviors and mechanisms of nickel-based oxygen carriers doped by Fe/Co during chemical looping combustion from multiple-scale molecular modeling combined with experiments

Understanding reactive behaviors and mechanisms of oxygen carriers (OCs) is a key issue in chemical looping combustion (CLC), which can provide ideas and routes not only for constructing high-performance OCs, but also for designing reactors and systems intensification. However, various points about...

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Bibliographic Details
Published in:Fuel processing technology Vol. 229; p. 107181
Main Authors: Zhang, Jinpeng, Zhang, Hui, Yuan, Nini, Meng, Liangliang, Geng, Chang, Bai, Hongcun
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 01-05-2022
Elsevier Science Ltd
Subjects:
Chemical bonds
Chemical looping combustion
Cobalt
Decomposition reactions
DFT
Doping
Fluidized bed combustion
Gravimetric analysis
Iron
Multiple-scale molecular modeling
Ni-based oxygen carriers
Nickel
Oxygen
Reaction mechanism
Surface structure
Reaction mechanism
DFT
Multiple-scale molecular modeling
Ni-based oxygen carriers
Chemical looping combustion
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Summary:Understanding reactive behaviors and mechanisms of oxygen carriers (OCs) is a key issue in chemical looping combustion (CLC), which can provide ideas and routes not only for constructing high-performance OCs, but also for designing reactors and systems intensification. However, various points about the reaction behaviors and oxygen release mechanism of iron/cobalt-doped nickel-based OCs in CLC remain unclear and highly desired to elucidate. Therefore, this work determines reactive behaviors and mechanisms of Fe/Co-doped nickel-based OCs using multiple-scale molecular modeling and experiments. The interaction between molecules and OCs surfaces was characterized using independent gradient modulus to directly visualize interaction region, type, and intensity; they were further quantified through energy decomposition analysis. The reaction path and coordinates in elementary reactions were explored based on DFT calculations, and the structures, energies, and electronic properties were obtained. According to calculated reaction energy barriers, Fe doping enhanced activity of nickel-based OCs, whereas Co doping reduced. Furthermore, nickel-based OCs were prepared and tested using thermo-gravimetric analysis (TGA) and temperature-programmed H2 reduction. Despite slight numerical differences, TGA-based apparent activation energies agreed well with DFT predications. Additionally, the effects of chemical bonding, surface structure, particle size and defects of OCs on the intrinsic and non-intrinsic reactive properties were revealed based on material characterizations. [Display omitted] •Reaction behaviors and mechanisms of Fe/Co-doped Ni-based OCs are determined by molecular modeling and experiments.•Interaction region, type, and intensity between reacting molecules and OCssurface directly visualized by IGM and EDA.•TGA-based apparent activation energies agree with DFT reaction energy barriers.•Chemical bonding, surface structure, particle size and defects can affect intrinsic and non-intrinsic OCs reactivity.
ISSN:0378-3820
1873-7188
DOI:10.1016/j.fuproc.2022.107181