2019
DOI: 10.1039/c8ta08932a
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Recent advances in lithium containing ceramic based sorbents for high-temperature CO2 capture

Abstract: Recently, lithium containing ceramic based high-temperature CO2 sorbents have received tremendous attention due to their high CO2 capture capacity, low regeneration temperatures, and relatively high stability.

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Cited by 123 publications
(64 citation statements)
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References 201 publications
(283 reference statements)
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“…[2][3][4] Low-temperature sorbents (based on amines, silica, zeolites, carbon, and MOFs) are mainly used for postcombustion CO 2 capture from ue gas at low temperatures (25 to 75 C), while high-temperature sorbents are specically developed for pre-combustion capture between 500 and 700 C. [2][3][4] "Pre-combustion capture" is one of the most challenging but best ways to tackle climate change as CO 2 is captured during the process at high temperatures with ideally zero release into the environment. [5][6][7] Pre-combustion capture is potentially less expensive than post-combustion capture, as CO 2 gets captured as soon as it is produced during the process without releasing it into the environment. [5][6][7] Although a large body of work has been carried out for postcombustion low-temperature CO 2 capture, 2 there are very few high temperature pre-combustion CO 2 capture processes.…”
Section: Introductionmentioning
confidence: 99%
“…[2][3][4] Low-temperature sorbents (based on amines, silica, zeolites, carbon, and MOFs) are mainly used for postcombustion CO 2 capture from ue gas at low temperatures (25 to 75 C), while high-temperature sorbents are specically developed for pre-combustion capture between 500 and 700 C. [2][3][4] "Pre-combustion capture" is one of the most challenging but best ways to tackle climate change as CO 2 is captured during the process at high temperatures with ideally zero release into the environment. [5][6][7] Pre-combustion capture is potentially less expensive than post-combustion capture, as CO 2 gets captured as soon as it is produced during the process without releasing it into the environment. [5][6][7] Although a large body of work has been carried out for postcombustion low-temperature CO 2 capture, 2 there are very few high temperature pre-combustion CO 2 capture processes.…”
Section: Introductionmentioning
confidence: 99%
“…to form NaHCO3 or KHCO3 at temperatures < 100 °C [79]- [86]. Li is typically investigated in ternary metal oxide systems [54], e.g. Li2ZrO3 or Li4SiO4, as is discussed in Section 5.3.…”
Section: Thermodynamic Properties Of Alkali Metal Oxide Sorbentsmentioning
confidence: 99%
“…This raises the question as to whether the use of high lithium content materials is feasible as their full regeneration could lead to higher energy penalties incurred in their use. While it is beyond the scope of this review to fully explore all studies on Li and Na containing oxides, readers are directed to a number of excellent recent reviews that cover these materials in much more depth [54], [481].…”
Section: Mgo and Nano3 Interface) This Hypothesis Was Supported Expementioning
confidence: 99%
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“…To increase the useful energy of these system and decrease the operating costs, intermediate-temperature and high-temperature sorbents, including hydrotalcites [4], MgO-based sorbents [5], calcium oxides [6][7][8][9], and ceramic materials [10][11][12], have been examined as alternative sorbents because these materials can directly separate CO2 from hot flue gases in thermal power or sorption-enhanced steam methane reforming (SE-SMR) processes. Alkaline ceramic materials [13], especially lithium orthosilicate (Li4SiO4) [14,15], appear to be attractive sorbents because they have high theoretical CO2 capture capacities (36.7 wt.%), and a consistent recyclability.…”
Section: Introductionmentioning
confidence: 99%