Challenges and opportunities for the utilisation of ionic liquids as solvents for CO<sub>2</sub>capture

Mota-Martinez, Maria T.; Brandl, Patrick; Hallett, Jason P.; Dowell, Niall Mac

doi:10.1039/c8me00009c

Cited by 76 publications

(75 citation statements)

References 79 publications

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“…[1,2] The ideal process would certainly be a one-pot solution in which the device could capture, activate, and transform the CO 2 available from different sources (ideally from air and exhaust gases). [3] Ionic liquids (ILs, Figure 1), mainly those that are thermally, photo-, electro-, and chemically stable and display very low vapor pressures, [4] are among the most promising materials to perform this multitask transformation. [5,6] The first report showing that certain ILs can sorb up to 0.6 mole fraction of CO 2 at 8 MPa [7] has opened a new window of opportunity for CO 2 capture and transformation.…”

Section: Introductionmentioning

confidence: 99%

The Nature of Carbon Dioxide in Bare Ionic Liquids

2020

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Section: Introductionmentioning

confidence: 99%

The Nature of Carbon Dioxide in Bare Ionic Liquids

2020

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“…1 − 3 Due to their peculiar physicochemical characteristics, IL solutions are ideal solvents for many reaction, separation, and extraction processes. 4 − 7 Several studies have pointed out their utility in gas capture 8 − 10 and separation, highlighting that the absorption capability strongly depends on the local liquid structure 11 and mechanism of gas confinement. 12 − 14 …”

Section: Introductionmentioning

confidence: 99%

Xenon Dynamics in Ionic Liquids: A Combined NMR and MD Simulation Study

et al. 2020

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The translational dynamics of xenon gas dissolved in room-temperature ionic liquids (RTILs) is revealed by 129 Xe NMR and molecular dynamics (MD) simulations. The dynamic behavior of xenon gas loaded in 1-alkyl-3-methylimidazolium chloride, [C n C 1 im]Cl ( n = 6, 8, 10), and hexafluorophosphate, [C n C 1 im][PF 6 ] ( n = 4, 6, 8, 10) has been determined by measuring the 129 Xe diffusion coefficients and NMR relaxation times. The analysis of the experimental NMR data demonstrates that, in these representative classes of ionic liquids, xenon motion is influenced by the length of the cation alkyl chain and anion type. 129 Xe spin–lattice relaxation times are well described with a monoexponential function, indicating that xenon gas in ILs effectively experiences a single average environment. These experimental results can be rationalized based on the analysis of classical MD trajectories. The mechanism described here can be particularly useful in understanding the separation and adsorption properties of RTILs.

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“…The fact that CCS is included in the system incorporates further challenges besides biomass conversion at large scale. The solvent regeneration step has been extensively studied, which highly depends in the composition of CO 2 in the gas [49], solvent use [50,51,52], or even on the degree of heat integration [41]. Therefore, co-firing biomass with natural gas is an attractive alternative to counteract all possible disadvantages.…”

Section: Whereas Combustion Entails a Complete Oxidation Of Biomass mentioning

confidence: 99%

Natural gas and BECCS: A comparative analysis of alternative configurations for negative emissions power generation

Cumicheo

Dowell

Shah

2019

International Journal of Greenhouse Gas Control

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There is a reliance on negative emissions technologies (NETs), primarily in the form of Bioenergy with Carbon Capture and Storage (BECCS) in most Integrated Assessment Model (IAM) scenarios which are capable of limiting the maximum global temperature rise to 1.5-2 • C. Two currently independent features of transition pathways are fuel switching from coal to gas, and the deployment of BECCS. The former makes natural gas an important transition fuel which at the same time could be combined with biomass to further abate emissions. To date the majority of studies have considered BECCS in the context of a conversion from coal-fired base configuration. There is therefore a pressing need to identify routes for the effective utilisation of biomassderived fuels in the context of gas-fired power generation infrastructure. In this contribution, we study three distinct CCS-based processes which combine natural gas and biomass capable of producing low-, or carbon-negative power. Both fuel supply chains are considered in order to quantify the net CO 2 emissions. An important insight is the configuration-specific impact of biomass co-combustion on the overall carbon intensity of power generated. We found that an external biomass combustion configuration was the most carbon negative, removing between 0.5-1 ton of CO 2 per MWh of power generated. Results revealed a trade-off between carbon negativity and efficiency of the processes. The generation of net carbon negative power is observed to be highly sensitive to the carbon footprint of the biomass supply chain.

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Challenges and opportunities for the utilisation of ionic liquids as solvents for CO₂capture

Cited by 76 publications

References 79 publications

The Nature of Carbon Dioxide in Bare Ionic Liquids

The Nature of Carbon Dioxide in Bare Ionic Liquids

Xenon Dynamics in Ionic Liquids: A Combined NMR and MD Simulation Study

Natural gas and BECCS: A comparative analysis of alternative configurations for negative emissions power generation

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Challenges and opportunities for the utilisation of ionic liquids as solvents for CO2capture

Cited by 76 publications

References 79 publications

The Nature of Carbon Dioxide in Bare Ionic Liquids

The Nature of Carbon Dioxide in Bare Ionic Liquids

Xenon Dynamics in Ionic Liquids: A Combined NMR and MD Simulation Study

Natural gas and BECCS: A comparative analysis of alternative configurations for negative emissions power generation

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Challenges and opportunities for the utilisation of ionic liquids as solvents for CO₂capture