Atomistic modeling toward high-efficiency carbon capture: A brief survey with a few illustrative examples

Maiti, Amitesh

doi:10.1002/qua.24579

Cited by 16 publications

(17 citation statements)

References 123 publications

(190 reference statements)

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“…The H 2 /SF 6 and H 2 /CH 4 ideal permselectivities are higher than 500 and 15, respectively, well above the respective values for the Knudsen selectivity of 8.5 and 2.8. SF 6 can only diffuse through defects in the zeolite lm. Diffusion of adsorbing gases through 8MR zeolites at moderate temperatures is governed by surface diffusion.…”

Section: Single Gas Permeationmentioning

confidence: 99%

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High flux high-silica SSZ-13 membrane for CO₂separation

et al. 2014

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High-silica (gel Si/Al ¼ 100) SSZ-13 membranes were prepared by hydrothermal secondary growth on the surface of a-alumina hollow fiber supports. The membranes were evaluated for their performance in the separation of CO 2 from equimolar mixtures with CH 4 or N 2 . The maximum CO 2 -CH 4 and CO 2 -N 2 separation selectivities were found to be 42 and 12 respectively, with a high CO 2 permeance of 3.0 Â 10 À7 mol m 2 s À1 Pa À1 at 293 K and total feed pressure of 0.6 MPa. At the low aluminum content, the prepared membranes contain a very low number of defects, as follows from their H 2 /SF 6 ideal selectivity of over 500 in the 293-473 K temperature range. Due to their hydrophobicity, water in the feed mixture has only a small influence on the permeance at temperatures above 353 K. Water improves the CO 2 -N 2 and CO 2 -CH 4 selectivity, which is attributed to preferential blocking of the hydrophilic, non-zeolitic defect pores. The hydrothermal stability of the high-silica SSZ-13 membrane was evaluated by a long (220 h) CO 2 -N 2 separation test with a humidified (9.5 kPa H 2 O) feed mixture at 393 K and 0.6 MPa feed pressure. The permeance and selectivity were stable during this endurance test, underpinning the promise of high-silica SSZ-13 membranes for application in the separation of hot and humid gas mixtures. † Electronic supplementary information (ESI) available: Including schemes of experimental setup and membrane module, SEM images of support surface and seed layer, details of adsorption simulations, TGA analysis of detemplation process, mixture separation in pressure gradient mode, water and gas adsorption isotherms, analysis of defect inuence. See

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Section: Single Gas Permeationmentioning

confidence: 99%

“…4 Capturing CO 2 is technologically very challenging and it is estimated to account for 50-90% of the total cost in the CCS/CCU chain. 6,7 Drawbacks of this industrial process are the cyclic operation and the high energy penalty. 6,7 Drawbacks of this industrial process are the cyclic operation and the high energy penalty.…”

Section: Introductionmentioning

confidence: 99%

High flux high-silica SSZ-13 membrane for CO₂separation

et al. 2014

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“…16 Should CO 2 exhibit higher affinity to the rock formations than hydrocarbons, it could help increase production. Understanding the relation between competitive adsorption and transport of CO 2 and hydrocarbons in rock formations is considered crucial to optimize both CO 2 storage capacity 17 and natural gas production.…”

Section: Introductionmentioning

confidence: 99%

CO₂–C₄H₁₀ Mixtures Simulated in Silica Slit Pores: Relation between Structure and Dynamics

Striolo

Cole

2015

J. Phys. Chem. C

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Equilibrium molecular dynamics simulations were conducted for pure n-butane and for mixtures containing n-butane and carbon dioxide confined in 2 nm wide slit-shaped pores carved out of cristobalite silica. A range of thermodynamic conditions was explored, including temperatures ranging from sub-critical to super-critical, and various densities. Preferential adsorption of carbon dioxide near the -OH groups on the surface was observed, where the adsorbed CO 2 molecules tend to interact simultaneously with more than one -OH group. Analysis of the simulation results suggests that the preferential CO 2 adsorption to the pore walls weakens the adsorption of n-butane, lowers the activation energy for n-butane diffusivity, and consequently enhances n-butane mobility. The diffusion results obtained for pure CO 2 are consistent with strong adsorption on the pore walls, as the CO 2 self-diffusion coefficient is low at low densities, increases with loading, and exhibits a maximum as the density is increased further because of hindrance effects. As the temperature increases, the maximum in self-diffusion coefficient is narrower, steeper and shifted to lower loading. The simulation results are also quantified in terms of molecular density profiles for both butane and CO 2 and in terms of residence time of the various molecules near the solid substrate. Our results could be useful for designing separation devices and also for better understanding the behavior of fluids in sub-surface environments.

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“…236 The importance of considering the dipole and quadrupole moments of solutes was also highlighted when looking at the solubility of gases in ionic liquids; this area has gained much attention in recent years, mainly focused around capture and storage of greenhouse gases. [240][241][242][243] A classical molecular dynamics study investigated the solubility of a number of different gases in the ionic liquid [Emim][N(SO 2 CF 3 ) 2 ]; they found that both hydrogen sulphide (which has a signicant dipole moment) and carbon dioxide (no dipole moment but with a large quadrupole moment), were highly soluble. In contrast, molecular hydrogen and nitrogen, with no dipole or quadrupole moments, were much less soluble.…”

Section: Case Studies: the Utility Of Combining Computational And Expmentioning

confidence: 99%

Computational approaches to understanding reaction outcomes of organic processes in ionic liquids

2015

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Atomistic modeling toward high-efficiency carbon capture: A brief survey with a few illustrative examples

Cited by 16 publications

References 123 publications

High flux high-silica SSZ-13 membrane for CO₂separation

High flux high-silica SSZ-13 membrane for CO₂separation

CO₂–C₄H₁₀ Mixtures Simulated in Silica Slit Pores: Relation between Structure and Dynamics

Computational approaches to understanding reaction outcomes of organic processes in ionic liquids

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Atomistic modeling toward high-efficiency carbon capture: A brief survey with a few illustrative examples

Cited by 16 publications

References 123 publications

High flux high-silica SSZ-13 membrane for CO2separation

High flux high-silica SSZ-13 membrane for CO2separation

CO2–C4H10 Mixtures Simulated in Silica Slit Pores: Relation between Structure and Dynamics

Computational approaches to understanding reaction outcomes of organic processes in ionic liquids

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High flux high-silica SSZ-13 membrane for CO₂separation

High flux high-silica SSZ-13 membrane for CO₂separation

CO₂–C₄H₁₀ Mixtures Simulated in Silica Slit Pores: Relation between Structure and Dynamics