Dual functional catalytic materials of Ni over Ce-modified CaO sorbents for integrated CO2 capture and conversion

Sun, Hongman; Wang, Jianqiao; Zhao, Jinhui; Shen, Boxiong; Jun, Shi; Huang, Jun; Wu, Chunfei

doi:10.1016/j.apcatb.2018.11.040

Cited by 228 publications

(140 citation statements)

References 75 publications

(72 reference statements)

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“…Additionally, Sun et al [125] employed a common CO 2 sorbent, CaO, directly as support material for Ni nanocatalysts with adjacent Ce-species. They argued that the already established calcium-looping process that rests on the carbonization and calcination of CaO for CO 2 capture and sequestration (CCS) could be modified through the integration of a CO 2 utilization step by converting CO 2 to CO.…”

Section: Dual-function Materials For Products Other Than Methanementioning

confidence: 99%

The Role of Alkali and Alkaline Earth Metals in the CO2 Methanation Reaction and the Combined Capture and Methanation of CO2

et al. 2020

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CO2 methanation has great potential for the better utilization of existing carbon resources via the transformation of spent carbon (CO2) to synthetic natural gas (CH4). Alkali and alkaline earth metals can serve both as promoters for methanation catalysts and as adsorbent phases upon the combined capture and methanation of CO2. Their promotion effect during methanation of carbon dioxide mainly relies on their ability to generate new basic sites on the surface of metal oxide supports that favour CO2 chemisorption and activation. However, suppression of methanation activity can also occur under certain conditions. Regarding the combined CO2 capture and methanation process, the development of novel dual-function materials (DFMs) that incorporate both adsorption and methanation functions has opened a new pathway towards the utilization of carbon dioxide emitted from point sources. The sorption and catalytically active phases on these types of materials are crucial parameters influencing their performance and stability and thus, great efforts have been undertaken for their optimization. In this review, we present some of the most recent works on the development of alkali and alkaline earth metal promoted CO2 methanation catalysts, as well as DFMs for the combined capture and methanation of CO2.

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Section: Dual-function Materials For Products Other Than Methanementioning

confidence: 99%

The Role of Alkali and Alkaline Earth Metals in the CO2 Methanation Reaction and the Combined Capture and Methanation of CO2

et al. 2020

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“…The metal-support interaction (Panaritis et al, 2018; Ronda-Lloret et al, 2018; Wang and Liu, 2018) as well as the effect of ceria in the dispersion of the active phase (Wang et al, 2013; Lu and Kawamoto, 2014; Wang L. et al, 2017; Sun et al, 2019) have a strong effect on the activity for the RWGS reaction. The role of ceria in dispersing the active phase seems particularly relevant in determining the selectivity toward CO.…”

Section: Co2 Hydrogenation To Value Added Chemicals Other Than Methanementioning

confidence: 99%

Ceria-Based Materials in Hydrogenation and Reforming Reactions for CO2 Valorization

2019

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Reducing greenhouse emissions is of vital importance to tackle the climate changes and to decrease the carbon footprint of modern societies. Today there are several technologies that can be applied for this goal and especially there is a growing interest in all the processes dedicated to manage CO 2 emissions. CO 2 can be captured, stored or reused as carbon source to produce chemicals and fuels through catalytic technologies. This study reviews the use of ceria based catalysts in some important CO 2 valorization processes such as the methanation reaction and methane dry-reforming. We analyzed the state of the art with the aim of highlighting the distinctive role of ceria in these reactions. The presence of cerium based oxides generally allows to obtain a strong metal-support interaction with beneficial effects on the dispersion of active metal phases, on the selectivity and durability of the catalysts. Moreover, it introduces different functionalities such as redox and acid-base centers offering versatility of approaches in designing and engineering more powerful formulations for the catalytic valorization of CO 2 to fuels.

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“…sorbent attrition [7]. Recently, an integrated carbon capture and utilization (ICCU) process has been proposed to combine the regeneration of sorbent and catalytic conversion of the captured CO2 in a single fixed bed reactor under isothermal conditions [8][9][10], which can reduce the energy required for sorbent regeneration, the infrastructure to transport and store captured CO2.…”

Section: Introductionmentioning

confidence: 99%

“…( 1) is a promising reaction for the utilization of CO2 because carbon monoxide (CO) acts as a feedstock to produce fuels and chemicals via Fischer-Tropsch process [11,12]. In our previous work, the ICCU process has been proven for the CO production [8]. The captured CO2 was converted into CO in a single reactor under isothermal conditions using one-pot method synthesized DFMs, which exhibited a good stability after 20 cycles of ICCU process.…”

Section: Introductionmentioning

confidence: 99%

Direct and highly selective conversion of captured CO2 into methane through integrated carbon capture and utilization over dual functional materials

Sun

Zhang

Guan

et al. 2020

Journal of CO2 Utilization

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Excessive atmospheric CO2 emission is regarded as one of the main factors causing global climate change. Thus, there is an urgent need to explore the possibility of CO2 capture and converting the captured CO2 to fuels or value-added products. Recently, an integrated carbon capture and utilization (ICCU) process performed in a single reactor under isothermal conditions draws intensive attentions due to the reduction of energy requirement for sorbent regeneration. However, from literature, normally a low loading of sorbent in dual functional materials (DFMs) was applied resulting in a very low CO2 capture capacity and consequent low CH4 yield in the ICCU process.Herein, we demonstrate the intermediate-temperature DFMs using inexpensive high-capacity MgO sorbent. The synthesized DFMs are a physical mixture of sorbent and Ru/CeO2 catalyst by the mass ratio of 2:1 allowing simultaneous regeneration of sorbent and conversion of CO2 in a single reactor at 300 ˚C. During the 1 st cycle of ICCU process, 10Ru/CeO2-MgO exhibits the best ICCU performance with the highest CH4 yield of 7.07 mmol g -1 and CO2 conversion of 89%. However, after 10 cycles of ICCU process, 5Ru/CeO2-MgO exhibits the highest CH4 yield (3.36 mmol g -1 ) and CO2 conversion (79%), which are much higher than that of 2.5Ru/CeO2-MgO (1.14 mmol g -1 and 39%) and 10Ru/CeO2-MgO (2.31 mmol g -1 and 69%). It is mainly attributed to that more oxygen vacancies are remained in 5Ru/CeO2-MgO resulted from the metal-support interaction.

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Dual functional catalytic materials of Ni over Ce-modified CaO sorbents for integrated CO2 capture and conversion

Cited by 228 publications

References 75 publications

The Role of Alkali and Alkaline Earth Metals in the CO2 Methanation Reaction and the Combined Capture and Methanation of CO2

The Role of Alkali and Alkaline Earth Metals in the CO2 Methanation Reaction and the Combined Capture and Methanation of CO2

Ceria-Based Materials in Hydrogenation and Reforming Reactions for CO2 Valorization

Direct and highly selective conversion of captured CO2 into methane through integrated carbon capture and utilization over dual functional materials

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