Mechanism of steam‐declined sulfation and steam‐enhanced carbonation by DFT calculations

Yang, Peng; Sun, Zhao; Duan, Lunbo; Tang, Hongjian

doi:10.1002/ghg.1905

Cited by 24 publications

(7 citation statements)

References 34 publications

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“…Moreover, the presence of steam during the carbonation stage exerts a positive influence on the overall performance of the sorbent, as inferred by comparing, respectively, the results for T600W vs. T600D, and T650W vs. T650D. This positive effect can be associated with the enhanced diffusion of CO 2 inside the porous network of the sorbent particle in presence of steam, with the development of a more favorable sorbent morphology and energy related to the CO 2 capture process by CaO, along with the formation of ionic (OH − ) species, in presence of H 2 O, as widely discussed in literature 3,15,39–45 . On the other hand, at higher temperature, H 2 O starts to promote sorbent sintering phenomena, 46,47 and this could explain why T700W ( Ν = 1 ➔ X Ca = 45.4% and N = 10 ➔ X Ca = 12.9%; average 20.8%) did not show the best result among the tests.…”

Section: Resultsmentioning

confidence: 91%

Performance of limestone‐based sorbent for sorption‐enhanced gasification in dual interconnected fluidized bed reactors

et al. 2022

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A possibility to carry out sorption‐enhanced gasification (SEG) is represented by its integration with the calcium looping concept in dual interconnected fluidized beds (DIFB). This article is focused on the sorbent CO2 uptake performance and attrition/fragmentation tendency when operating conditions simulating those of a DIFB‐SEG process are adopted. Experiments were carried out on a commercial Italian limestone in a laboratory‐scale DIFB reactor. Carbonation was carried out in a range of test conditions, including variable temperature (600–700°C) and absence/presence of steam (10% by volume); CO2 concentration was set at 10% by volume. The characterization is extended by investigating the behavior of preprocessed DIFB‐SEG samples on impact fragmentation tests, conducted in an ex situ apparatus. Tests were carried out for impact velocities in the range 17–45 m/s. Results were discussed considering both the impact velocity value and the operating conditions under which the sample was preprocessed in the fluidized bed.

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Section: Resultsmentioning

confidence: 91%

Performance of limestone‐based sorbent for sorption‐enhanced gasification in dual interconnected fluidized bed reactors

et al. 2022

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“…When the atoms exhibit more overlapping electron orbitals, more stable bonds are generated; therefore, the chemisorption of CO 2 is stronger on Ce-promoted CaO. 36,46 As shown in Figure 6b, the peaks of C and O 1 atoms shift toward lower energy after CO 2 adsorption, which indicates the chemisorption of CO 2 and high stability of the generated CO 3 2− structure on Ce-promoted CaO. Besides, more resonance peaks of Ce and O 1 atoms appear, demonstrating that the interaction between the two atoms is responsible for strong CO 2 adsorption on the Ce-promoted CaO surface.…”

Section: Resultsmentioning

confidence: 99%

Density Functional Theory Study on CO₂ Adsorption by Ce-Promoted CaO in the Presence of Steam

Yan

Zhao

et al. 2020

Energy Fuels

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Calcium looping is one of the most promising technologies for large-scale CO2 capture, while CaO-based materials suffer from the deactivation in CO2 capture capacity in the multiple carbonation/calcination cycles as a result of sintering. Ce-promoted CaO is considered as an effective CO2 sorbent during calcium looping cycles. In this paper, the CO2 adsorption performance of Ce-promoted CaO in the presence of steam was investigated using density functional theory (DFT) calculations. The cyclic CO2 capture performance of Ce-promoted CaO in the presence of steam was tested to confirm the feasibility of DFT calculations. Moreover, the structural and adsorption parameters, including atomic layout, energy, bond length, and charge transfer of CO2 and H2O molecules on Ce-promoted CaO, were determined. The DFT calculation results indicate that the surface O atoms in Ce-promoted CaO are activated by the Ce atom; therefore, the CO2 adsorption performance is improved on Ce-promoted CaO. When the H2O molecule is pre-adsorbed on Ce-promoted CaO and CaO, the adsorption of CO2 is enhanced. The CO2 adsorption energies on Ce-promoted CaO and CaO in the presence of H2O are −1.99 and −1.53 eV, respectively, which are larger than those in the absence of H2O. The co-adsorption of CO2 and H2O molecules appears feasible on Ce-promoted CaO, while CaO exhibits obvious inhibition on the co-adsorption. The experimental results indicate that the Ce species in Ce-promoted CaO exist in the form of CeO2, which leads to higher CO2 capture activity and sintering resistance than those of CaO. The presence of steam in carbonation improves the CO2 capture capacity of Ce-promoted CaO; therefore, the experimental results agree well with DFT calculations. The cost of makeup flow of Ce-promoted CaO is 20.3% lower than that of CaO. Therefore, Ce-promoted CaO appears promising in calcium looping.

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“…The influences of different additives on CaO-based sorbents and gas impurities, such as steam and SO 2 , were evaluated using DFT calculations from an atomic viewpoint. [32][33][34] In contrast, the reaction mechanism related to ionic transfer during the chlorination reaction of CaO was not systemically researched in previous studies. Hence, the change in the chlorination reactivity of CaO and the corresponding mechanism are worth understanding for optimization of the HCl removal process.…”

Section: Introductionmentioning

confidence: 99%

A DFT study on the mechanism of HCl and CO₂ capture by CaO

Huang

Feng

et al. 2022

React. Chem. Eng.

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Mechanism of steam‐declined sulfation and steam‐enhanced carbonation by DFT calculations

Cited by 24 publications

References 34 publications

Performance of limestone‐based sorbent for sorption‐enhanced gasification in dual interconnected fluidized bed reactors

Performance of limestone‐based sorbent for sorption‐enhanced gasification in dual interconnected fluidized bed reactors

Density Functional Theory Study on CO₂ Adsorption by Ce-Promoted CaO in the Presence of Steam

A DFT study on the mechanism of HCl and CO₂ capture by CaO

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Mechanism of steam‐declined sulfation and steam‐enhanced carbonation by DFT calculations

Cited by 24 publications

References 34 publications

Performance of limestone‐based sorbent for sorption‐enhanced gasification in dual interconnected fluidized bed reactors

Performance of limestone‐based sorbent for sorption‐enhanced gasification in dual interconnected fluidized bed reactors

Density Functional Theory Study on CO2 Adsorption by Ce-Promoted CaO in the Presence of Steam

A DFT study on the mechanism of HCl and CO2 capture by CaO

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Density Functional Theory Study on CO₂ Adsorption by Ce-Promoted CaO in the Presence of Steam

A DFT study on the mechanism of HCl and CO₂ capture by CaO