CO2 chemisorption in Li2CuO2 microstructurally modified by ball milling: study performed with different physicochemical CO2 capture conditions

Lara-García, Hugo A.; Ramírez-Moreno, Margarita J.; Ortíz-Landeros, José; Pfeiffer, Heriberto

doi:10.1039/c6ra06895b

Cited by 29 publications

(13 citation statements)

References 38 publications

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“…In the absence of oxygen supply from the air flow, oxygen atoms have to be released from the structure of lithium tungsten oxide, and this anionic crystalline diffusion could limit the carbonation process. 23 Our dynamic CO 2 sorption results indicate that Li 6 WO 6 with NW morphology has significant potential for CO 2 sorption at a range of high temperatures. The BET measurements indicate a surface area of 8.1 m 2 /g for NW powder.…”

Section: Nano Lettersmentioning

confidence: 70%

“…In line with previous reports, for the case of lithium tungstate, the oxygen from air seems to assist the carbonation process on adsorbents. In the absence of oxygen supply from the air flow, oxygen atoms have to be released from the structure of lithium tungsten oxide, and this anionic crystalline diffusion could limit the carbonation process . Our dynamic CO 2 sorption results indicate that Li 6 WO 6 with NW morphology has significant potential for CO 2 sorption at a range of high temperatures.…”

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confidence: 92%

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Low-Temperature and Fast Kinetics for CO₂ Sorption Using Li₆WO₆ Nanowires

et al. 2018

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In this paper, lithium hexaoxotungstate (LiWO) nanowires were synthesized via facile solid-state reaction and were tested for CO capture applications at both low (<100 °C) and high temperatures (>700 °C). Under dry conditions, the nanowire materials were able to capture CO with a weight increment of 12% in only 60 s at an operating temperature of 710 °C. By contrast, under humidified ambience, LiWO nanowires capture CO with weight increment of 7.6% at temperatures as low as 30-40 °C within a time-scale of 1 min. It was observed that the CO chemisorption in LiWO is favored in the oxygen ambience at higher temperatures and in the presence of water vapor at lower temperatures. Nanowire morphology favors the swift lithium supply to the surface of lithium-rich LiWO, thereby enhancing the reaction kinetics and lowering time scales for high capacity adsorption. Overall, high chemisorption capacities, superfast reaction kinetics, wide range of operating temperatures, and reasonably good recyclability make 1-D LiWO materials highly suitable for various CO capture applications.

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Section: Nano Lettersmentioning

confidence: 70%

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confidence: 92%

Low-Temperature and Fast Kinetics for CO₂ Sorption Using Li₆WO₆ Nanowires

et al. 2018

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“…In the process of CCS, CO 2 is captured from flue gas and stored for utilization and sequestration instead of being released to the environment directly. Recent studies have found that various lithium-based materials, such as LiFeO 2 [6], Li 2 CuO 2 [7], Li 2 ZrO 3 [7,8,9], Li 8 SiO 6 [10,11], and Li 4 SiO 4 [9], are capable of effective CO 2 capture. Among these materials, Li 4 SiO 4 , with a variety of applications [12,13], has better application potential, owing to its higher CO 2 sorption capacity, cyclic stability than LiFeO 2 , Li 2 CuO 2 , and Li 8 SiO 6 , and lower cost than that of Li 2 ZrO 3 [9].…”

Section: Introductionmentioning

confidence: 99%

Performance of Li4SiO4 Material for CO2 Capture: A Review

Yan

et al. 2019

IJMS

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Lithium silicate (Li4SiO4) material can be applied for CO2 capture in energy production processes, such as hydrogen plants, based on sorption-enhanced reforming and fossil fuel-fired power plants, which has attracted research interests of many researchers. However, CO2 absorption performance of Li4SiO4 material prepared by the traditional solid-state reaction method is unsatisfactory during the absorption/regeneration cycles. Improving CO2 absorption capacity and cyclic stability of Li4SiO4 material is a research highlight during the energy production processes. The state-of-the-art kinetic and quantum mechanical studies on the preparation and CO2 absorption process of Li4SiO4 material are summarized, and the recent studies on the effects of preparation methods, dopants, and operating conditions on CO2 absorption performance of Li4SiO4 material are reviewed. Additionally, potential research thoughts and trends are also suggested.

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“…In this line, recently it has been shown that different CO 2 sorbents [19] , i.e., Na 2 ZrO 3 can be used as bifunctional materials, acting first as a CO 2 captor and then as a catalytic material for methane reforming reaction, presenting a clearly advantages over the procedure proposed by Gorin and Retallik. Other CO 2 material captors, namely alkali (Li, Na and K) [20][21][22][23][24][25] and alkalineearth (Be, Mg and Ca) [26][27][28][29] metal-based ceramics have shown high ability for CO 2 capture. Therefore, all these ceramics may be promissory carbonated materials for hydrogen production through dry methane reforming.…”

Section: Introductionmentioning

confidence: 99%